Kuimov An

Cloning and characterization of TNKL, a member of tankyrase gene family

By serological screening of a breast tumor cDNA library we have identified a novel human gene, tnkl, encoding an ankyrin-related protein with a high degree of similarity to tankyrase, the poly(ADP-ribose)polymerase associated with human telomeres (Smith et al, Science 282: 1484). The tnkl gene maps to chromosome 10, while the tnks gene encoding tankyrase is located on chromosome 8. The predicted 1166-aa protein product of the tnkl gene is 78% identical to human tankyrase and 62% to a putative D. melanogaster protein. Since the proteins have essentially identical domain structures, the corresponding genes form a distinct gene family. The possible link between TNKL and cancer justifies its further functional analysis.

Immunohistochemical detection of tankyrase 2 in human breast tumors and normal renal tissue

Tankyrase, which functions at telomeres and other cellular compartments, is thought to be a positive regulator of telomerase; its isoenzyme tankyrase 2 has been cloned as a putative cancer antigen. This pilot immunohistochemical study was designed to examine whether tumors overexpress tankyrase 2. An antibody was generated by using synthetic peptide specific for tankyrase 2 and was tested by Western blot and immunocytochemically; no cross-reaction with isoenzyme 1 was revealed. Among tissue sections, two tumors of 18 specimens were positive for tankyrase 2. Others were negative or contained barely detectable protein. The surrounding normal tissues were negative. Tankyrase 2 was also revealed in epithelial cells of a limited number of normal renal tubules, whereas other renal tissues were negative. These data suggest that tankyrase 2 is not expressed ubiquitously in human tissues. To determine whether the up-regulation of tankyrase 2 is associated with tissue regeneration and cell proliferation, we compared the activity and concentration of the enzyme in a model human embryonic kidney cell line 293 arrested by serum deprivation and restimulated with serum. The serum-starved quiescent cell culture exhibited detectable protein as did the proliferating cells; enzyme activity dramatically increased in the latter. We conclude that pathologic overexpression of tankyrase 2 in some tumors may be a result of the cancer-related adaptation of the malignant cells dependent on tankyrase activity. Under normal conditions, the protein might be up-regulated during cell differentiation and also posttranslationally in proliferating cells.

Polypeptide components of telomere nucleoprotein complex

Chromosome telomeres of humans and many model organisms contain a structure called a t-loop, which is maintained by TERF, TINF2, Pot1, and other proteins. Increase in TERF1 concentration prevents telomere elongation by telomerase. Decrease in TERF2 concentration (preventing t-loop formation) is accompanied by blockade of proliferation and appearance of other signs of cellular senescence in experiments. Natural regulation of TERF1 involves tankyrase, ATM protein kinase, and fluctuations of the protein level across a cell cycle. The telomere nucleoprotein complex also interacts with various polypeptide macromolecules (e.g., Sir2, PinX1, Rap1, Ku, Rad50/Mre11/Nbs1) responsible for heterochromatin formation, modulation of telomerase activity, DNA repair, and signaling to other cell compartments about telomere state. Study of structure and functioning of telomere nucleoprotein complex may contribute to elucidation of poorly understood mechanisms of aging and processes of tumor transformation of cells.

Interaction of Afobazole with σ1-Receptors

In vitro radioligand assay revealed interaction of afobazole with σ1-receptors (Ki=5.9 × 10—6 M). Translocation of σ1-receptors from the endoplasmic reticulum to the outer membrane was demonstrated by confocal microscopy. Experiments were performed on the model of HT-22 immortalized hippocampal cells after incubation with afobazole in a concentration of 10—8 M.

Soluble Tankyrase Located in Cytosol of Human Embryonic Kidney Cell Line 293

We studied the subcellular localization of tankyrase in primary and immortalized human cell cultures. In embryonic kidney cell line 293 the enzyme was excluded from the nuclei and distributed in fractions of soluble cytosolic proteins and low-density microsomes. Newly revealed cytosolic tankyrase in its poly(ADP-ribosyl)ated form was passed through a Sepharose 2B column and eluted as an apparently monomeric protein. The cytosolic localization of the enzyme correlated with its relatively high activity in the 293 cell line in comparison to eight other studied cell types.

Poly(ADP-ribosyl)ation of mannose-binding lectin out of human kidney cells

Mannose-binding lectin was identified as a substrate of tankyrase 2, an enzyme that catalyzes poly(ADP-ribosyl)ation. The endogenous tankyrase 2 was isolated out of cytoplasm of human embryonic kidney cells. It was bound to a soluble complex of at least two other proteins; they were identified using specific antibodies and other approaches as keratin 1 and mannose-binding lectin. Using immunoblot analysis and radioactive labeling, we detected tankyrase-2-dependent poly(ADP-ribosyl)ation of mannose-binding lectin. In the presence of NAD+, the complex of keratin 1 and lectin was dissociated, what was recorded during elution of its separate components out of affinity columns and by decrease of their apparent molecular masses during gel-filtration. Tankyrase 2 also inhibited the carbohydrate-binding function of the lectin. The latter effect was observed using mannose-binding lectin out of human serum, which is free from keratin 1. As a result of tankyrase-2 activity, the lectin lost its affinity to mannan-agarose. The discovery of this new biochemical mechanism justifies further analysis of its physiological and medical significance.

Isolation and physicochemical properties of tankyrase of human embryonic kidney cells of line 293

We have isolated and purified endogenous cytosolic tankyrase from human embryonic kidney cells of line 293. Our data confirm a model of De Rycker and Price who consider that tankyrase is a master scaffolding protein capable of regulating assembly of large protein complexes. We have also studied kinetic characteristics of tankyrase in the complex, pH dependence of the enzyme activity, and its physicochemical properties.

Tankyrase Activity in Organs and Tissues of Mice.

Tankyrase, one of the NAD+ ADP-ribosyltransferases, is a target for drugs developed for their anticancer and other pharmacological activities. We designed an assay for estimation of the inhibition or activation of the enzyme in pre-clinical studies. In mice, the highest specific activity of tankyrase was observed in thymus, spleen, pancreas, and bone marrow. In murine liver, tankyrase is active in ontogenesis and during reparative regeneration; however, the basal activity is hardly detectable in normal liver and most of other organs of adult animals. We suggest that tankyrase is a part of the tissue growth and repair machinery, while its age-dependent inhibition, when an organism stops growing, turns on phenoptosis.