Radiation-induced cell cycle arrests in Ehrlich ascites carcinoma cells in vivo

Radiation-induced progression delay in G₁/S, S and G₂/M phases of p53 wild-type Ehrlich ascites carcinoma (EAC) cells growing in vivo was investigated by DNA flow cytometry. Different behavior patterns of EAC cells at the time after irradiation with low (2, 4, 6, 8 Gy) and high (10, 15, 20 Gy) doses were evaluated. While EAC cells showed a small progression delay in S phase and a dose-dependent block in G₂/M phase after the irradiation with low doses, a clear additional block in G₁/S phase was observed after irradiation with high doses. An assessment of the damage response and repair networks at the time after irradiation might have important implication for the development of cancer management and treatment.     

Isolation of replication forks from growing Ehrlich ascites cells

A procedure is described which permits the large-scale isolation of essentially complete replications forks from the DNA of Ehrlich ascites cells. The whole nuclear DNA is first isolated by a method which involves minimal hydrodynamic shear. The DNA is then degraded by cryolysis, a freeze-thawing procedure, to a size providing the otherwise very labile forked structures with a sufficient resistance against shear forces. Finally, the Y-shaped structures of replicating DNA are separated by nitrocellulose column chromatography. When the newly formed strands of replicating DNA were density-labeled with 5-bromodeoxyuridine the DNA fraction isolated by this procedure banded in isopycnic CsCl gradients at a density expected for Y-shaped molecules with two light-heavy branches and one light-light branch and sedimented significantly faster than the corresponding bulk DNA fraction through neutral sucrose gradients. The forked molecules could be visualized by electron microscopy. The essential step of the procedure is the cryolysis which produces fragments from larger DNA structure essentially at random. When the cryolysis is omitted the forked structures are disrupted within the highly susceptible regions around the branching point.     

Cell volume regulation in Ehrlich ascites tumor cells

Ehrlich cells subjected to anisoosmolar media show very rapid volume changes. In hypertonic media they shrink. In hypotonic media they swell but the rapid initial swelling is followed by a regulatory shrinkage lasting ca. 30 minutes. Cells suspended in media with identical ionic concentrations but different total osmolarity (adjusted by sucrose) were compared. These studies revealed that swollen cells adjust their volume by decreasing the amount of intracellular K⁺ and ninhydrin positive substances. Intracellular Na⁺ and ATP concentrations were unchanged. Accordingly ⁴²K⁺ flux analysis showed that the (passive) cell membrane permeability for K⁺ is increased to a minor degree and the Na⁺ permeability unaffected. The increased K⁺ permeability could not be correlated to an increase in ⁴⁵Ca²⁺ influx.     

Malate-citrate cycle during glycolysis and glutaminolysis in Ehrlich ascites tumor cells

The malate-citrate cycle was studied during aerobic glycolysis and glutaminolysis in a strain of Ehrlich ascites tumor cells which showed a very low malate-aspartate shuttle system activity. The experimental approach includes: estimation of mitochondrial NAD[P]+-dependent malic enzyme activity; respiratory activity of freshly harvested or fasted cells, and of isolated mitochondria; and determination of the metabolites involved in the glycolytic and glutaminolytic pathways. The results suggest that in this strain, the malate-citrate shuttle is not an effective pathway for transferring glycolytic reducing equivalents from cytosol to mitochondria. Less than 15% of the glucose uptake was affected by the 1,2,3-benzenetricarboxylate inhibition of the malate-citrate shuttle. Moreover, in the presence of glucose, the malate-citrate cycle did not appear to play an important role in the glutaminolytic process. The present work supports and extends the finding of previous studies, since the results showed that the glucose metabolism depressed the oxidative processes in Ehrlich ascites tumor mitochondria, not only alone, but also in the presence of glutamine. Interestingly, the high glutamine uptake was maintained in the presence of glucose.     

Cell cycle-dependent expression of nuclear matrix proteins of Ehrlich ascites cells studied by in vitro translation

A combination of methods was used to study the cell cycle-dependent expression of nuclear matrix proteins of Ehrlich ascites cells: Separation of asynchronous cells growing in vivo into fractions of G1-, S- and G2- phase cells by centrifugal elutriation with less than 10% cross-contamination. Isolation of poly(A+) RNA populations from total cytoplasmic RNA by affinity chromatography on messenger affinity paper (mAP). In vitro translation of poly(A+) RNA from asynchronous and phase synchronous cells. Immunoprecipitation of in vitro synthesized nuclear matrix proteins by a monoclonal antibody with anti-lamin specificity (PKB8) and by a polyspecific anti-nuclear matrix serum (AMS5) followed by analysis of immunoprecipitated materials on SDS-polyacrylamide gels. The results indicate that mRNAs for nuclear matrix-associated proteins including the lamins B and C are either exclusively or at least predominantly present in the cytoplasm of cells in S phase suggesting a high rate of in vivo synthesis of these proteins during S phase. This is consistent with an anticipated biological function of the nuclear matrix which is considered to organize parental and newly synthesized DNA in higher order structures.     

Kinetics of histone methylation in vivo and its relation to the cell cycle in Ehrlich ascites tumor cells.

The appearance of methylated lysines in newly synthesized histones from Ehrlich ascites tumor cells was measured during one generation time. Newly synthesized histones were pulse-labeled in vivo by L-[3H]lysine, and the time course of the uptake of label into monomethyl, dimethyl and trimethyllysine from gel-electrophoretically isolated histones F2a1 (H4) and F3 (H3) was followed. Methylation starts immediately after histone biosynthesis. It proceeds, however, more slowly than histone synthesis. Both the rate of methylation and the mechanism of methylation in F3 and F2a1 histones differ. F3 methylation can be described by a first-order reaction, i.e. the reaction rate depends only on the concentration of free methylation sites available. Rate constants of approximately 0.21 h-1 were found for all three methylation steps. Methylation in the F2a1 histone proceeds more slowly than in F3. The dimethylation step in this fraction can be described by a zero-order reaction with a rate constant which is the reciprocal of the duration of the DNA synthesis phase. Alternatively this step could be correlated with the transition of the cells from the S phase into the G2 phase. By the end of one generation time all methylation sites in all F2a1 and F3 molecules are occupied by methyl groups at a ratio of about 1:3:1 for monomethyl, dimethyl and trimethyllysine in the F3 histone. In the F2a1 molecule the methyllysines consist mainly of dimethyllysine.     

Cell cycle related studies on thymidine kinase and its isoenzymes in Ehrlich ascites tumours

Thymidine kinase (TK) activity was measured in relation to the cell cycle of in vivo growing ascites tumour cells. The cells were synchronized by means of centrifugal elutriation and the cell cycle composition of the cell fractions was determined by flow cytometry. TK activity was low in G1, increased during S phase and declined in G2. A half-life of TK activity of about 45 min was found throughout the cell cycle. Four isoenzymes at pI values of 4.1, 5.3, 6.9 and 8.3, denoted as isoenzymes 1-4, were identified using isoelectric focusing. Isoenzymes 3 and 4 were responsible for the profound cell cycle related changes in the TK activity. Corresponding isoenzymes were also found in the fetal mouse liver. In the adult mouse liver isoenzyme 2 was the dominating isoenzyme. The half-life of the isoenzymes was in the same range as for the total TK activity. We conclude that the low TK activity in G1 is due to degradation of the enzyme in G2 at a normal rate combined with an arrest in the synthesis of TK. We also conclude that isoenzyme 4 and the intermediate isoenzyme 3, which had earlier been suggested to be a mitochondrial form of TK, in fact represent cytoplasmatic forms of TK. According to cell cycle and pI studies, isoenzyme 2 belongs to the mitochondrial form. Studies with various phosphor donors and specific substrates, however, indicate that it also contains a cytoplasmic component.     

Synchronization of replicons in Ehrlich ascites cells

Ehrlich ascites cells, in which replication units at the beginning of the S phase started and grew synchronously, were obtained by the following protocol: (1) selection of G1 cells by zonal centrifugation, (2) hypoxia for 12 h, (3) reaeration, (4) addition of cycloheximide (30 microM) within the first minute after reoxygenation. Studies on the effectiveness of the different steps revealed: (i) G1 cells reoxygenated after 12 h of hypoxia traverse two succeeding cell cycles highly synchronously. This was shown by monitoring the thymidine incorporation rate, the thymidine pulse-labeling index, and the mitotic index. (ii) Cycloheximide, like hypoxia, suppresses replicon initiation in Ehrlich ascites cells without interfering with DNA chain growth and DNA maturation. The reversibility of the suppression is less complete than in the case of hypoxia. This was shown by DNA fiber autoradiography and by analyzing the length distribution of pulse- or pulse/pulse-chase-labeled daughter DNA in alkaline sucrose gradients. The alkaline sedimentation patterns of daughter-strand DNA, pulse labeled immediately after the cycloheximide addition at the end of the elaborated protocol and 1 and 2 h later, indicated synchronous initiation and growth of a homogeneous population of DNA molecules to replicon-sized lengths.     

Interaction andin vivo growth inhibition of Ehrlich ascites tumor cells by jacalin

Jacalin has been found to agglutinate Ehrlich ascites cells. The agglutination was inhibited by α-glycosides of D-Gal and β -D-Gal(1 → 3)-D-GalNAc suggesting that the lectin-ascites interaction was carbohydrate-specific. There was 21.8% inhibition of tumour (ascites) cell growthin vivo in mice administered 50μg of jacalin by injection for 6 days following intraperitoneal injection of ascites cells. Administration of 100, 150 and 200μg jacalin resulted in 40.2, 57.5 and 83% inhibition respectively. Thein vivo inhibition of tumour cells growth by jacalin was due to its preferential binding with D-Gal-α -(1 → 6) present as terminal residues in the glycoprotein on tumour cell surface.     

Neutral glycosphingolipids in Ehrlich ascites carcinoma cells

The structure of the neutral glycosphingolipids of the Ehrlich ascite carcinoma (EAC) cells was studied. The main four components were identified as glycosylceramide, lastosylceramide, N-acetylgalactosyllactosylceramide and galactosyl-N-acetyllactosylceramide (asialo-GM1). The neutral glycolipid pattern of the cells was found to depend on their density. Dilution of the cell suspension resulted in an increased content of asia-lo-GM1, whereas the content of the other neutral glycolipids remained unchanged. The possible connection between these changes and the earlier disclosed cell density dependence of the gangliosides in EAC cells is discussed.     

Mannose toxicity in Ehrlich ascites tumor cells

Mannosephosphate isomerase (MPI) showed a higher activity than hexokinase (HKM) in its ability to phosphorylate mannose in the spleen, thymus, brain, liver, striated muscles, kidneys, and testes from BALB/c mice. This led to a HKM/MPI ratio of less than 1 in all the organs and tissues mentioned. In contrast, Ehrlich ascites tumor cells obtained from the peritoneum of BALB/c mice had low MPI activity (half of the HKM activity and, therefore, a ratio of 2). Mannose, which is nontoxic to nontumor cells at a concentration of 0.1 M, induced marked in vitro mortality of the tumor cells. Incubation of Ehrlich ascites tumor cells with mannose resulted in a high accumulation of mannose-6-phosphate and a marked depletion of ATP which did not appear when the cells were incubated with glucose. These facts may explain the selective mortality caused by mannose in the tumor cells studied.