The effect of some platinum compounds on the activity of the CTP synthetase of Ehrlich ascites tumor cells: in vitro and in vivo studies.

The present work investigates the effect of cis-DDP (DDP, diamminedichloroplatinum(II)), trans-DDP, SPC (spermine platinum(II) complex), and K2PtCl4 on the activity of the CTP synthetase in the cytosol of Ehrlich ascites tumor cells. To study their in vitro effect, the platinum compounds were supplemented to the incubation mixture for the enzyme assay. A concentration dependent inhibition of the CTP synthetase was found which was strongest in the case of trans-DDP. When ascites cells collected from mice, pretreated in vivo with platinum compounds, were used, the enzyme assay showed that the inhibition is strongest in the case of cis-DDP and K2PtCl4 (about 90% inhibition). This distinct inhibitory effect of the platinum compounds in the present experiments may be explained with the metabolic conversions of the compounds in the organism to their more active forms and/or with the inhibition of the protein biosynthesis under their influence because the lifetime of the CTP synthetase is short. This last assertion is proved in this work by control experiments with the antibiotic cycloheximide, which is an inhibitor of the protein biosynthesis.

The effect of some platinum compounds on the biosynthesis of RNA and its precursors.

The effect of cis-DDP (cis-diamminedichloroplatinum(II)), trans-DDP (trans-diamminedichloroplatinum(II)), SPC (spermine-platinum(II) complex), and K2PtCl4 on the ribomononucleotide and RNA metabolism was studied. When Ehrlich ascites tumor cells were preincubated with the aforementioned compounds and then labeled with [C14]uridine a clear-cut suppression of the radioactive labeling of RNA was observed. As radioactivity incorporated into the pool of the free uridine nucleotides in the cells treated with platinum compounds was even higher in comparison with that of the non-treated cells a conclusion may be drawn with certainty that the platinum compounds studied inhibit RNA biosynthesis. It was also found that under the effect of these compounds in the in vivo-assessed rate of the conversion of uridine nucleotides into cytidine nucleotides was considerably diminished. Using NaH14CO3 as a radioactive precursor it was shown that platinum compounds also inhibited purine biosynthesis de novo, in particular the conversion of IMP into GMP and AMP. The pronounced inhibitory effect of the platinum compounds on essential steps of the pyrimidine and purine biosynthesis de novo may be at least partly responsible for the firmly established inhibition in the present study of RNA biosynthesis by platinum compounds. The inhibition of the synthesis of the mononucleotides and RNA by the platinum compounds may be closely related to their cytostatic and cytotoxic activities.

Supercoils in plant DNA: nucleoid sedimentation studies.

Plant nuclei have been studied with respect to the three-dimensional structure of DNA. Nucleoids derived from nuclei by non-ionic detergent and high salt treatment were analysed by sedimentation in a series of sucrose gradients containing increasing amounts of the intercalating agent ethidium bromide. In addition the nucleoid sedimentation behaviour was investigated following gamma irradiation. The results show that plant DNA is supercoiled, as is the DNA from the other eukaryotes studied, and contains approximately the same concentration of superhelical turns but probably relatively fewer DNA superhelical loops. The plant nuclear populations in all cases studied give rise to two distinct nucleoid bands. These have been characterized by electron microscopy and by their DNA and protein content. The possible origin of the two bands is discussed.

Free pyrimidine nucleotide pool of Ehrlich ascites-tumour cells. Characteristics related to quantitative studies of RNA metabolism.

Ehrlich ascites-tumour cells incubated in a mineral medium supplemented with glucose and glutamine intensely incorporated labelled uridine into free nucleotides and RNA. Detailed kinetic studies of the labelling of total acid-soluble pools of uridine and cytidine nucleotides and of RNA under standard conditions and after chase with non-radioactive uridine were carried out. The relative distribution of the radioactivity between the individual uridine phosphates as well as their total cellular contents were also determined under standard and chase conditions. The labelling kinetics of the mononucleotides and RNA by radioactive uridine and orotate were compared, and some turnover parameters were estimated by mathematical analysis of a steady-state model. The following conclusions were drawn. (1) The observed chase effect of addition of non-radioactive uridine is due to a rapid expansion of the acid-soluble uridine nucleotide pool and consequently a severalfold lowering of its specific radioactivity. (2) The free uridine nucleotides are partly separated into a large and a small compartment, labelled preferentially by exogeneous orotate and uridine respectively. (3) The half-life of the mononucleotides, at least those located in the smaller compartment, is a few minutes only, owing to a rapid exchange with the uridylic acid residues of unstable RNA species. (4) This process of reutilization of RNA-degradation products accounts for 85% (a minimum estimate) of the overall turnover of the nucleotide pool in resting cells.

Free pyrimidine nucleotide pool of Ehrlich ascites-tumour cells. Compartmentation with respect to the synthesis of heterogeneous nuclear RNA and precursors to ribosomal RNA.

The incorporation of [14C]orotate and [14C]uridine into UMP residues of hnRNA (heterogeneous nuclear RNA) and pre-rRNA (precursors to rRNA) of Eharlich ascites-tumour cells was compared: orotate was incorporated at a markedly higher rate into hnRNA. On the other hand, the rate of incorporation of uridine into pre-rRTNA was even somewhat higher than into hnRNA. The ratio of specific radioactivities of CMP to UMP residues in pre-rRNA and hnRNA was studied. At all times of labelling this ratio was similar for both RNA species independently of the precursor used. On addition of excess unlabelled uridine, the CMP/UMP labelling ratio in both pre-rRNA and hnRNA rose. However, this increase was much more pronounced with hnRNA. It is concluded that nuclear pyrimidine nucleotide pool for RNA synthesis is compartmentalized. The synthesis of hnRNa is supplied preferentially by the large and the small compartment, respectively. A detailed model for the cellular compartmentation of uridine nucleotide precursors to RNA is proposed.U

Changes of CTP synthetase activity during postnatal rat brain development.

The activity of CTP synthetase (UTP: ammonia ligase (ADP, EC. 6.3.4.2.) was determined in rat cerebral hemispheres and cerebellum during postnatal development. It was found that enzyme activity, when expressed per unit of protein or wet tissue weight, in both parts of the brain decreased with age, the diminution proceeding more rapidly in the cerebellum than in the hemispheres. When CTP synthetase was expressed on the basis of DNA an activity peak in the hemispheres with a maximum on the 5th day after birth was observed. The enzyme content per cell was several times lower in the cerebellum than in the hemispheres at each age studied, with the exception of 1-day-old animals, in which both tissues displayed similar activity. The results obtained were compared with literature data for the intensity of RNA synthesis in the developing brain. The conclusion was reached that the changes of CTP synthetase activity were closely related to the RNA metabolism. Therefore the enzyme under study may be one of the factors involved in cell control of RNA synthesis.