S-Adenosylmethionine and methylation.

S-Adenosylmethionine (AdoMet or SAM) plays a pivotal role as a methyl donor in a myriad of biological and biochemical events. Although it has been claimed that AdoMet itself has therapeutic benefits, it remains to be established whether it can be taken up intact by cells. S-Adenosylhomocysteine (AdoHcy), formed after donation of the methyl group of AdoMet to a methyl acceptor, is then hydrolyzed to adenosine and homocysteine by AdoHcy hydrolase. This enzyme has long been a target for inhibition as its blockade can affect methylation of phospholipids, proteins, DNA, RNA, and other small molecules. Protein carboxymethylation may be involved in repair functions of aging proteins, and heat shock proteins are methylated in response to stress. Bacterial chemotaxis involves carboxymethylation and demethylation in receptor-transducer proteins, although a similar role in mammalian cells is unclear. The precise role of phospholipid methylation remains open. DNA methylation is related to mammalian gene activities, somatic inheritance, and cellular differentiation. Activation of some genes has been ascribed to the demethylation of critical mCpG loci, and silencing of some genes may be related to the methylation of specific CpG loci. Viral DNA genomes exist in cells as extrachromosomal units and are generally not methylated, although once integrated into host chromosomes, different patterns of methylation are correlated with altered paradigms of transcriptional activity. Some viral latency may be related to DNA methylation. Cellular factors have been found to interact with methylated DNA sequences. Methylation of mammalian ribosomal RNAs occurs soon after the synthesis of its 47S precursor RNA in the nucleolus before cleavage to smaller fragments. Inhibition of the methylation of rRNA affects its processing to mature 18S and 28S rRNAs. The methylation of 5'-terminal cap plays an important role in mRNA export from the nucleus, efficient translation, and protection of the integrity of mRNAs. Another important function of AdoMet is that it serves as the sole donor of an aminopropyl group that is conjugated with putrescine to form, first, the polyamine spermidine, and then spermine.

Glycosphingolipid composition of murine neuroblastoma cells: O-acetylesterase gene downregulates the expression of O-acetylated GD3.

We have studied the glycosphingolipid composition in an F-11 neuroblastoma cell line originated from hybridization of a mouse neuroblastoma cell line (N18TG-2) with rat dorsal root ganglion cells. The total lipid-bound glucose of F-11 cells was estimated to be 0.28 micrograms/mg of protein and the total lipid-bound sialic acid was 0.82 micrograms/mg of protein. The major neutral glycosphingolipids were Gb4 (37% of the total neutral glycosphingolipids), Gb3 (15%), LacCer (21%), and GlcCer (15%). The major gangliosides were found to be GM3 (37% of the total gangliosides), GD3 (27%), O-acetylated GD3 (18%), and GD1a (4%), with trace amounts of GD2. The unusually high concentration of O-acetylated GD3 is consistent with its putative role as a tumor marker. Immunocytochemical localization studies of GD3 and O-acetylated GD3, examined by mouse monoclonal antibodies R24 and D1.1, respectively, revealed that the cell bodies and processes were all positively stained. To elucidate the role of O-acetylated GD3 in tumorigenesis, we transfected F-11 cells with the O-acetylesterase gene from influenza C virus. Compared with the original cell line, the transfected cells showed a dramatic increase in the level of GD3 (150% of that in the control cells) and a significant decrease of the concentration of O-acetylated GD3 (27% of control cells). In addition, the transfected F-11 cells exhibited a morphology different from the parental cells with enlarged cell bodies and elongated neurites. We conclude that alteration of ganglioside composition, particularly the expression of GD3 and O-acetylated GD3, may be associated with the morphological changes observed in this cell line.(ABSTRACT TRUNCATED AT 250 WORDS)

Defective DNA topoisomerase I activity in a DNAts mutant of Balb/3T3 cells.

Cell and polyomavirus DNA synthesis in ts20, a temperature-sensitive mutant derived from Balb/3T3 cells, is inhibited at an early step in chain elongation in vivo and in vitro. Virus DNA synthesized under restrictive conditions, when analyzed by gel electrophoresis and fluorography, contained a series of equally spaced bands migrating between form I and form II. If restrictive conditions were prolonged, the relative amount of these less-supercoiled topoisomers increased while the overall amount of virus DNA decreased. DNA topoisomerase I activity was lower and more heat-labile when prepared from mutant cells compared to wild-type and revertant cells. An assay in which extracts from wild-type cells corrected defective cell DNA synthesis in lysed mutant cells was applied to purification of the active factor from such extracts. Salt fractionation and three cycles of column chromatography resulted in the isolation of the activity in a fraction containing 10 major polypeptides. The specific activity in the final preparation was increased fivefold and was accompanied by the activity of DNA topoisomerase I. Our results provide evidence that DNA topoisomerase I functions at an early step in chain elongation of cell and polyomavirus DNA synthesis and that the enzyme activity may be decreased as a result of the mutation in ts20.

Further characterization of the phenotype of ts20, a DNAts mutant of BALB/3T3 cells.

Ts20 is a temperature-sensitive mutant cell line derived from BALB/3T3 cells that is blocked at a step in DNA synthesis involving chain elongation. Following a shift from 33 degrees to 39 degrees C, mutant cells lost ability to grow or form colonies. When mutant cells were infected with polyomavirus, both cell and virus DNA synthesis were inhibited at the restrictive temperature of 39 degrees C. When cell extracts from wild-type cells were added in vitro to lysed infected mutant cells that had been incubated in vivo at 39 degrees C for expression of the mutation, cell DNA synthesis was increased 3-fold (similar to the effect in uninfected mutant cells), whereas virus DNA synthesis was increased only 60%. With harsher lysis conditions, the effect of added extract on virus DNA synthesis was greater, although baseline DNA synthesis (prior to addition of extracts) was much lower. Analysis by alkaline sucrose gradients showed that the addition of cell extract converted small cellular DNA molecules into larger ones, while it increased the synthesis of small virus DNA molecules rather than completed genomes. Analysis of cytosol extracts (in which the activity stimulating DNA synthesis resides) showed that DNA topo-isomerase I activity was more heat-labile when assayed in mutant extracts compared to wild-type extracts. In contrast, cytosol DNA polymerase activity was equally heat-labile in mutant and wild-type extract. This suggested the factor in extract was likely associated with the activity of DNA topo-isomerase I. Analysis of virus DNA synthesized in vitro in restricted mutant cells by gel electrophoresis and fluorography showed an accumulation of topo-isomers migrating between form I and II. These topo-isomers, thought to be a manifestation of the ts defect, did not disappear when extract from wild-type cells was added back in vitro or when mutant cells were shifted back to permissive temperature prior to lysis for in vitro synthesis. The results indicate that polyoma DNA synthesis and cell DNA synthesis differ in their response to the mutant gene product in ts20, although both are inhibited at a step early in DNA chain elongation that may involve DNA topo-isomerase I.

Characterization of a ts mutant of BALB/3T3 cells and correction of the defect by in vitro addition of extracts from wild-type cells.

ts20 is a temperature-sensitive mutant cell line derived from BALB/3T3 cells. DNA synthesis in the mutant decreased progressively after an initial increase during the first 3 h at the restrictive temperature. RNA and protein synthesis increased for 20 h and remained at a high level for 40 h. Cells were arrested in S phase as determined by flow microfluorimetry, and DNA chain elongation was retarded as measured by fiber autoradiography. Infection with polyomavirus did not bypass the defect in cell DNA synthesis, and the mutant did not support virus DNA replication at the restrictive temperature. After shift down to the permissive temperature, cell DNA synthesis was restored whereas virus DNA synthesis was not. Analysis of virus DNA synthesized at the restrictive temperature showed that the synthesis of form I and replicative intermediate DNA decreased concurrently and that the rate of completion of virus DNA molecules remained constant with increasing time at the restrictive temperature. These studies indicated that the mutation inhibited ongoing DNA synthesis at a step early in elongation of nascent chains. The defect in virus and cell DNA synthesis was expressed in vitro. [3H]dTTP incorporation was reduced, consistent with the in vivo data. The addition of a high-salt extract prepared from wild-type 3T3 cells preferentially stimulated the incorporation of [3H]dTTP into the DNA of mutant cells at the restrictive temperature. A similar extract prepared from mutant cells was less effective and was more heat labile as incubation of it at the restrictive temperature for 1 h destroyed its ability to stimulate DNA synthesis in vitro, whereas wild-type extract was not inactivated until incubated at that temperature for 3 h.