Enhanced expression of viral polypeptides and messenger RNA in dimethyl sulfoxide and bromodeoxyuridine-treated Friend erythroleukemic cells

Dimethyl sulfoxide inhibits the expression of early growth-response genes and arrests fibroblasts at quiescence

We have previously shown that dimethyl sulfoxide (DMSO) treatment of mouse embryo fibroblasts (MEF) at the early hours of mitogenic stimuli resulted in the inhibition of DNA and protein synthesis; delayed treatment of serum-stimulated cells with DMSO had little effect on the synthesis of these macromolecules. Here, we demonstrate the specific inhibition of expression of early growth response genes by DMSO in serum-stimulated MEF. The expression of interleukin 6, and of oncogenes c-myc and c-fos were inhibited when the cells were treated with 2% DMSO from the beginning of serum-stimulated growth but not after 3 h of mitogenic stimuli. Although the actin gene is an early serum-response gene, its expression was not affected by DMSO. The synthesis of another serum-induced protein, the plasminogen activator inhibitor-1 was blocked during concurrent and delayed (after 3 h of stimulation) treatment of serum-stimulated fibroblasts with DMSO. The expression of glyceraldehyde-3-phosphate dehydrogenase gene was not affected by DMSO. These results indicate that the expression of non-growth-related genes are either not affected or affected nonspecifically both at early and late stages of serum-induced growth of mouse embryo fibroblasts. The serum-induced expression of c-fos gene was abolished by DMSO treatment of MEF while the phorbol 12-myristate 13-acetate-induced expression of fos gene was not, indicating that the PMA signaling pathway was refractory to DMSO. Treatment of cells with medium containing 2% DMSO for 24-48 h prevents them from progression into cell cycle by preventing the expression of genes involved in G0-G1 transition of quiescent cells.

Dimethyl sulfoxide affects the amount of extrachromosomal spleen focus-forming virus DNA in murine erythroleukemia cells

We used Southern blot hybridization to titrate and map restriction enzyme cleavage sites of a 6.3-kilobase-pair species of extrachromosomal viral DNA found in derivatives of the 745A line of murine erythroleukemia cells, which vary in their ability to be induced to differentiate by dimethyl sulfoxide (DMSO). Greater than an eightfold variation was observed in the amount of this DNA, with the largest amounts being found in cells that were resistant to the induction of differentiation by DMSO. This increase in the level of extrachromosomal viral DNA was found to be dependent upon the continued presence of DMSO in the culture medium. The increase was shown not to be due to an immediate stimulatory effect of this agent on the synthesis or maintenance of this DNA, since cell lines sensitive to the differentiation-inducing effects of DMSO were shown to undergo a transient reduction in the amount of extrachromosomal viral DNA after the addition of DMSO to the culture medium. In addition to the 6.3-kilobase-pair linear form found in the cytoplasm, in some preparations two hybridizing bands were observed that migrated in agarose gels in the position expected of covalently closed circular species of viral DNA. Restriction enzyme mapping of the cytoplasmic linear form indicated a close relationship of this DNA to two polycythemic strains of spleen focus-forming virus that have been molecularly cloned by other workers. No obvious change in the number or arrangement of chromosomal viral sequences could be detected after treating cells with DMSO. Thus, the exposure of murine erythroleukemia cells to DMSO caused an obvious change in the amount of extrachromosomal spleen focus-forming virus DNA but no obvious change in the integration of the provirus.

Modification of lipophilic proteins in Friend erythroleukemia cells during their differentiation

In mouse erythroleukemia cells (MELC) a lipophilic protein of apparent M.W. 9.5 kdaltons increases during differentiation. This increase is due either to an increase of biosynthesis or to a structural alteration impairing the capacity of the protein to form polymers of apparent high M.W. or favoring its extractability. The increases is related to differentiation and precedes hemoglobin synthesis by at least 1 day. It is not related to virus production because it occurs in cells (line F 4-1) which do not produce virus, but it does not occur in cells (TFA-II) in which dimethylsulfoxide (DMSO) causes an increase in virus production. As it occurs in cells treated with 4 different inducers, and as the increase is less marked when antagonists of the inducers are also present, it is unlikely that the increase of the 9.5 Kdalton protein is due to an effect of the inducers unrelated to differentiation.