Assembly and transcription of synthetic vesicular stomatitis virus nucleocapsids.

The functional template for transcription of vesicular stomatitis virus (VSV) RNA is a ribonucleoprotein particle (nucleocapsid) consisting of the negative-strand sense genomic RNA completely encapsidated by the viral nucleocapsid (N) protein. As an approach to create nucleocapsids in vitro, we demonstrate here the specific encapsidation by purified N protein of in vitro-synthesized RNA sequences representing the 5' end of both the negative- and positive-strand VSV genome-length RNAs. As few as 19 nucleotides from the 5'-end of positive-strand RNA allowed maximal encapsidation, although the 5' terminal 10 nucleotides would allow partial (50%) encapsidation. Sequences downstream of the binding site can be of any origin. Specific encapsidation of VSV sequences was dependent on the presence of uninfected cell cytoplasmic extracts or poly(A). The synthetic nucleocapsids have the properties of RNase resistance and a buoyant density typical of wild-type VSV nucleocapsids. We have encapsidated a synthetic virionlike RNA species which contained just the terminal sequences of the virion RNA: the N encapsidation signal from the 5' end and the leader gene from the 3' end. This assembled nucleocapsid could function in vitro as a transcription template for the VSV RNA polymerase.

Etoposide-induced DNA cleavage in human leukemia cells.

The nuclear enzyme, topoisomerase II, is the major site of action for cancer chemotherapy agents such as etoposide, teniposide, and a variety of intercalating agents. These compounds cause the enzyme to cleave DNA, forming a DNA-protein complex that may be a key step leading to cell death. It is apparently unique as a chemotherapy target, since drug potency diminishes with decreasing enzyme activity. It was thus of interest to examine the topoisomerase content and drug-induced DNA cleavage in freshly obtained human leukemia cells and to compare the obtained data with the results of similar studies performed in well-characterized human leukemia cell lines. The human T-lymphoblast line, CCRF-CEM, was more than 100-fold more sensitive to the DNA-cleavage effect of etoposide than the cells of the 13 leukemic patients examined. One of the leukemia lines (HL-60) and a lymphoblastoid line (RPMI-7666) were somewhat less sensitive than cells of the CCRF-CEM cells, but were still 10-fold more sensitive than the patients studied. The relative insensitivity of the freshly obtained cells could not be accounted for by differences with respect to drug uptake but were associated with markedly reduced topoisomerase-II content as assayed by immunoblotting using a mouse polyclonal serum against topoisomerase II. Heterogeneity was observed in the sensitivities of patients' cells with respect to both drug-induced DNA cleavage and enzyme content. The observed differences between cultured cell lines and patients' cells may have been related to their proliferative status. Etoposide potency in normal resting lymphocytes resembles that observed in circulating leukemia cells. However, following mitogenesis with phytohemagglutinin and interleukin-2, proliferating lymphocytes become as sensitive to etoposide as cultured cell lines with regard to DNA cleavage. This effect was accompanied by an increase in topoisomerase-II content. Our data thus support the hypothesis that topoisomerase-II content may be an important determinant of cell sensitivity to certain classes of chemotherapy agents. Efforts to stimulate topoisomerase-II content may improve the therapeutic efficacy of these drugs.

Characterization of acquired epipodophyllotoxin resistance in a Chinese hamster ovary cell line: loss of drug-stimulated DNA cleavage activity.

Recent evidence indicates that type II DNA topoisomerases mediate epipodophyllotoxin-induced DNA damage and may be intrinsic to the drug's antitumor effects. Using an epipodophyllotoxin-resistant cell line, we have now further defined the relationship between DNA damage and cell death and delineated the significance of certain drug-enzyme interactions. When compared to wild-type cells, the mutant Chinese hamster ovary cell line, VpmR-5, exhibits marked resistance to both the cytotoxic and DNA cleavage activities of etoposide (VP-16). Steady-state concentrations of radiolabeled VP-16 are identical in both cell lines. Catalytic activity in crude nuclear extracts from wild-type and VpmR-5 cells is equal and is equally sensitive to inhibition by VP-16. However, using an assay that specifically measures generation of 5' protein-linked breaks in 32P-labeled 3' DNA, we have found that DNA cleavage activity in nuclear extract from the VpmR-5 line is profoundly resistant to stimulation by VP-16. Further, a somatic cell hybrid line of VpmR-5 cells and drug-sensitive EOT-3 cells exhibits recovery of VP-16 sensitivity in concert with reconstitution of DNA cleavage activity. These data indicate that stimulation of enzyme-mediated DNA cleavage, rather than loss of normal topoisomerase function, is responsible for epipodophyllotoxin-induced cytotoxicity.

Proliferation dependence of topoisomerase II mediated drug action.

Topoisomerase II mediated DNA scission induced by both a nonintercalating agent [4'-demethylepipodophyllotoxin 4-(4,6-O-ethylidene-beta-D-glucopyranoside) (VP-16)] and an intercalator [4'-(9-acridinylamino) methanesulfon-m-anisidide (m-AMSA)] was studied as a function of proliferation in Chinese hamster ovary (CHO), HeLa, and mouse leukemia L1210 cell lines. Log-phase CHO cells exhibited dose-dependent drug-induced DNA breaks, while plateau cells were found to be resistant to the effects of VP-16 and m-AMSA. Neither decreased viability nor altered drug uptake accounted for the drug resistance of these confluent cells. In contrast to CHO cells, plateau-phase HeLa and L1210 cells remained sensitive to VP-16 and m-AMSA. Recovery of drug sensitivity by plateau-phase CHO cells was found to reach a maximum approximately 18 h after these cells regained exponential growth and was independent of DNA synthesis. DNA strand break frequency correlated with cytotoxicity in CHO cells; log cells demonstrated an inverse log linear relationship between drug dose (or DNA damage) and colony survival, whereas plateau-derived colony survival was virtually unaffected by increasing drug dose. Topoisomerase II activity, whether determined by decatenation of kinetoplast DNA, by cleavage of pBR322 DNA, or by precipitation of the DNA-topoisomerase II complex, was uniformly severalfold greater in log-phase CHO cells compared to plateau-phase cells.