[Telomerization as a method of obtaining immortal human cells preserving normal properties]. / Telomerizatsiia--sposob polycheniia immortal'nykh kletok cheloveka, sokhraniaiushchikh normal'nye svoistva.

Most human somatic cells have no telomerase activity. This leads to terminal underreplication of chromosomes and, hence, proliferative ageing of cells. We studied the consequences of introduction of the gene of the catalytic component of human telomerase hTERT in the normal fibroblasts of adult human skin. The expression of this gene led to the appearance of telomerase activity in the fibroblasts, elongation of telomeres (to the size characteristic of the embryonic cells), and immortalization. The cells retained their normal karyotype. The activity of ribosomal genes remained unchanged: the degree of their methylation, abundance, and transcriptional activity (two clones were studied). The cells did not undergo significant changes after transition over the Hayflick's limit, retained the constant rate of proliferation (one of the clones was followed to the level of 200 duplications of the population), and resembled, in appearance, young diploid human fibroblasts. The initial cells and cells transfected by an empty vector could pass through no more than 68 duplications, their proliferation slowed down and they acquired the morphology characteristic for the ageing cells. The telomerized cells retained the normal capacity of entering the proliferative rest as a result of serum starvation. Telomerization did not eliminate the contact inhibition of proliferation but led to an increased saturating density of cells, which reached the levels characteristic for the early embryonic cells. The long-term suppression of the telomerase function by azidothymidine led to a shortening of telomeres and significantly slowed down cell proliferation. The cells that did not divided for a long time were enlarged, preserved their viability, and resembled, in appearance, the ageing cells. In the test on heterokaryons (index of telomerase activity on the chromosomes inside the cell), the telomerized cells behaved as other immortal cells. All these data suggest that the telomerized cells preserved the normal mechanisms of regulation of cell proliferation.

Telomerase-dependent reactivation of DNA synthesis in macrophages implies alteration of telomeres.

In previous work we demonstrated that various types of cultured cells with a limited life span could not reactivate DNA synthesis in the nuclei of mouse peritoneal macrophages in heterokaryons. We now investigate the role of telomerase in the process of the macrophage nucleus reactivation in heterokaryons with immortal telomerase-positive 3T3 Swiss mouse fibroblasts and human fibroblasts with introduced hTERT gene. We report that introduction of the hTERT gene into human diploid fibroblasts results in emergence of telomerase activity in these cells and the ability to induce the reactivation of DNA synthesis in the macrophage nuclei in heterokaryons. Inhibition of telomerase activity in heterokaryons by reverse transcriptase inhibitors (azidothymidine and guanosine polyphosphonate analogues) and by a 2'-O-methyl-RNA oligonucleotide anti-sense to the template region of telomerase RNA, block reactivation of DNA synthesis in macrophage nuclei without inhibiting DNA synthesis in the nuclei of fibroblasts. Our results suggest alterations (shortening or damage) in the macrophage telomere structure. As far as we know, heterokaryons with macrophages are the first cellular model for rapid investigation of the effects of telomerase inhibitors.

[Effect of azidothymidine on reactivation of DNA synthesis in macrophage nuclei contained in heterokaryons]. / Vliianie azidotimidina na protsess reaktivatsii sinteza DNK v iadrakh makrofagov v sostave geterokarionov.

EIn heterokaryons, DNA synthesis is reactivated in macrophage nuclei only in the case of fusion with immortal cells. Assuming that telomerase is responsible for reactivation, the effect of its inhibitor azidothymidine (AZT) was studied in heterokaryons of mouse resident peritoneal macrophages and immortal 3T3 Swiss cells. AZT suppressed reactivation of DNA synthesis in macrophage nuclei and had no effect on DNA synthesis in 3T3 Swiss cell nuclei, suggesting an altered telomere structure in normal mouse macrophages.