Changes in thymidine kinase activity during differentiation of HL-60 leukemic cells

Mechanisms of nitrosothiol-induced antimitogenesis in aortic smooth muscle cells

The purpose of this work was to investigate the effect of a nitrosothiol vasodilator, S-nitroso-N-acetylpenicillamine (SNAP), on serum-induced cell proliferation, thymidine uptake, RNA synthesis, protein synthesis and thymidine kinase activity in a cultured rat aortic smooth muscle cell line. SNAP decreased the rate of serum-stimulated cell proliferation, thymidine uptake and incorporation, uridine and leucine incorporation and thymidine kinase activity in concentration-dependent fashion. The threshold concentration of SNAP for inhibition of cell proliferation and thymidine uptake was similar and in the range of 1-3 microM. Uridine incorporation, indicative of RNA synthesis, was inhibited beginning at 10 microM SNAP, whereas leucine incorporation, indicative of protein synthesis, and thymidine kinase activity, an enzyme of importance to DNA synthesis, were inhibited beginning at 100 microM SNAP. These results indicate that inhibition of cell proliferation induced by relatively low concentrations of SNAP (1-10 microM) is independent of inhibition of protein synthesis or thymidine kinase activity, whereas higher concentrations of SNAP may inhibit cell proliferation by decreasing protein synthesis.

Cytofluorometric assay for the determination of thymidine uptake and phosphorylation in living cells

Thymidine kinase is a key enzyme for the application of drugs in chemotherapy and for diagnosis. Although of great interest, its regulation during cell cycle and differentiation is difficult to study, as current techniques for isolation of cells in different phases of growth are unsatisfactory. An assay that allows the determination of enzymatic activity in situ in single cells would be much faster than present methods and would elegantly avoid synchronization procedures. We synthesized different analogues of thymidine with the 5-methyl group substituted by a fluorochrome. At least three of these compounds were phosphorylated by thymidine kinase in cell free extracts and were taken up and phosphorylated by cells in culture. The cytofluorometric signal of the accumulated fluorochrome in any given cell reflected the thymidine kinase activity of this cell. Simultaneous measurement of cell-cycle dependent parameters allowed the correlation of thymidine kinase activity with the phase of growth in mixed cell populations.

Flow cytometric measurement of rRNA levels detected by fluorescent in situ hybridization in differentiating K-562 cells

The flow cytometric detection of fluorescent in situ hybridization (FISH) performed on intact cells in suspension is a recently described method (Bauman et al. 1989). We studied the application of this method for monitoring cellular differentiation. The amount of rRNA which is taken for a good indicator of growth in size, the rate of protein synthesis and the G0 G1 transition was followed by FISH. For this purpose biotinylated single stranded RNA probes obtained by transcription from a 2.1 kb BglII-EcoRI fragment of the human 28S ribosomal RNA gene subcloned into plasmid pGEM2 were used. K-562 leukaemic cells, used as targets, were induced to differentiate by dimethyl sulfoxide, phorbol myristate acetate and hemin. In the last two cases the cell cycle analysis, growth kinetics, cellular morphology and immunophenotyping indicated differentiation into monocytic and erythroid direction, respectively. The differentiation was accompanied by a rapid increase followed by a decrease to the base level of rRNA. This was not observed in the uninduced exponentially growing control cells. Based on our results, we propose that the FC-FISH detection of the rRNA level is a valuable method to distinguish between cell subpopulations. We propose that using other probes, FC-FISH will become useful to monitor different cellular processes.

The role of blood platelets in nucleoside metabolism: regulation of megakaryocyte development and platelet production

In higher vertebrates, different types of blood cells develop from common precursors. Mammals are unique in possessing two types of blood cells--erythrocytes and platelets--which lack nuclei. Although platelets display consistent and easily-recognisable morphological and ultrastructural characteristics and show extreme metabolic and functional versatility, they are not true cells, being produced by fragmentation of giant polyploid precursors called megakaryocytes. At present, the physiological mechanisms which regulate megakaryocyte development and platelet production are not well understood. Platelets are actively involved in metabolism of purine derivatives and a significant platelet role in pyrimidine metabolism has also been demonstrated (see previous papers). Here an attempt is made to integrate information about platelet involvement in nucleic acid precursor metabolism with current concepts of haematopoiesis, particularly megakaryocyte development and platelet production. It is concluded (i) that megakaryocytic cells are immediate descendents of haematopoietic stem cells which have become polyploid as a result of genetic damage or metabolic imbalances, (ii) megakaryocytes and platelets are the ultimate regulators of stem cell development because they control the availability of thymidine and (iii) that the production of megakaryocytes and platelets is a physiological safety mechanism which prevents fixation of genetic damage and protects other cells from potentially cytotoxic and genotoxic stimuli.

Stimulation by tumor necrosis factor of HL-60 thymidine salvage pathway metabolism dissociated from proliferation

The effect of human tumor necrosis factor (TNF) on early-passage HL-60 cells was studied. A transient phase of increased [3H]thymidine (TdR) incorporation was noted at 20-24 hr of exposure to TNF. This increase was disproportionate to the much slighter stimulation of the percentage of S-phase cells, which was measured by flow cytometry. Evidence for increased metabolic trapping of [3H]TdR following TNF treatment was apparent from whole cell uptake experiments. The salvage pathway enzyme TdR kinase was therefore measured and was found to be elevated comparably to [3H]TdR uptake. The mechanism of TNF regulation of TdR kinase was further investigated by a series of combination treatment experiments using other biologic factors and pharmacologic inhibitors of various intracellular steps. The response to TNF was not potentiated or reproduced by IL-1, IL-2, IL-3, IL-4, G-CSF, M-CSF, GM-CSF or alpha- or gamma-interferon. Blockers of early signal transduction steps, including H7, W7, sphingosine, and pertussis toxin, failed to inhibit TNF stimulation of [3H]TdR incorporation. mRNA synthesis inhibition with alpha-amanitin blocked this TNF effect, as did cAMP but not cGMP analogues. A sensitizing effect was noted with amiloride or cytochalasin B, characterized by greater relative increases of [3H]TdR incorporation and TdR kinase activity in response to TNF. In the presence of cytochalasin B, TNF treatment resulted in no change or slight decreases in the percentage of S-phase cells. Regulation of TdR kinase could thereby be dissociated from the usual cell cycle control. This study thus documents a unique example of stimulation of thymidine salvage pathway metabolism by a biologic factor, dissociable from overall cell cycle regulation.

Changes in the activities of cytidine deaminase during differentiation of HL60 cells induced by 1,25 dihydroxy D3

The activities of the enzymes cytidine deaminase (CDD), deoxycytidine kinase (dCK), adenosine deaminase (ADA), and purine nucleoside phosphorylase (PNP), have been investigated in the promyelocytic leukemia cell line HL60. The activities of the enzymes corresponded well with that seen in acute myeloid leukemia cells except, that the CDD activity was very low in the HL60 cells. Induction of differentiation in HL60 cells by 1,25 dihydroxy D3 resulted in an increase in CDD from 12 to 247 nmol/h/mg and a decrease in ADA from 1326 to 896 nmol/h/mg, while the activities of dCK, and PNP were unchanged. Retinoic acid, another used inducer of differentiation, gave no changes of the enzyme activities. The increase in CDD activity induced by 1,25 dihydroxy D3 was prevented by inhibition of protein synthesis, whereas inhibition of proliferation of the cells did not abolish the increase of CDD. The changes correspond well with the differences seen between immature and mature myeloid cells. The results may have consequences for the interpretation of results obtained with cytostatics, which are metabolized by the enzymes.