Leon N. Kapp

Stable radioresistance in ataxia-telangiectasia cells containing DNA from normal human cells.

SV40-transformed ataxia-telangiectasia (AT) cells were transfected with a cosmid that contains a normal human DNA library and a selectable marker, the neo gene, which endows successfully transformed mammalian cells with resistance to the antibiotic G418. After a three-part selection protocol for G418 resistance and radioresistance, a cell line stably resistant to ionizing radiation was recovered. Cells from this line were irradiated with 50 Gy of X-rays and fused with non-transfected AT cells. Among the G418-resistant colonies recovered was one that was stably resistant to radiation. Resistance to ionizing radiation of both the primary transfectant line and its fusion derivative was intermediate between that of AT cells and normal cells, as assayed by colony-forming ability and measurement of radiation-induced G2 chromatid aberrations; both cell lines retained AT-like radioresistant DNA synthesis. These results suggest that, because radioresistance in the transfected cells was not as great as that in normal human cells, the two hallmarks of AT, radiosensitivity and radioresistant DNA synthesis, may still be the result of a single defective AT gene.

Regulation of protein secretion in Chinese hamster ovary cells by cell cycle position and cell density: Plasminogen activator, procollagen and fibronectin☆

Abstract To study the relationship between cell growth control, cell contact, and protein secretion, we examined the production of plasminogen activator, procollagen, and fibronectin by Chinese hamster ovary (CHO) fibroblasts, both as a function of position in the cell cycle and as a function of cell density. CHO fibroblasts that were synchronized at hourly intervals throughout the cell cycle by mitotic selection in an automated roller bottle apparatus secreted plasminogen activator only during the G2 and M phases of the cell cycle (10–14 h after mitotic selection). Cell-associated plasminogen activator activity was variable during G1 and S, but was greatly reduced during G2 and M. In contrast, secretion of the connective tissue matrix proteins, procollagen and fibronectin, was controlled by cell density rather than by cell cycle position. Type III procollagen and fibronectin were secreted throughout the cell cycle with no pronounced variations. Type I procollagen was not secreted by cycling cells and was observed in confluent cultures only after 24–48 h. To correlate these changes in protein secretion patterns with cell shape and contact, we used scanning electron microscopy (SEM) to study the appearance of CHO cells after mitotic selection. Actively dividing cells retained a high proportion of rounded, ruffled, and blebbed cells during all phases of the cell cycle. Only with increased cell density in contact-inhibited confluent cultures did most cells begin to flatten and spread. Thus, secretion of and attachment to extracellular matrix did not occur in rapidly dividing cells, but appeared to require the increased cell-cell contact and spreading that accompanies contact inhibition of growth. On the other hand, increased secretion of plasminogen activator was directly related to cell division and may be part of a sequence of events that allows cells growing in culture to loosen extracellular attachments in preparation for rounding and cytokinesis.

Replicon size and excision repair as factors in the inhibition and recovery of DNA synthesis from ultraviolet damage.

Initiation of DNA replication and chain growth, analyzed by alkaline sucrose gradient sedimentation, was interrupted to different extents in different cell types by irradiation with ultraviolet light. Within the first hour of irradiation DNA replication was reduced in a manner that depended on the average number of lesions per replicating unit (replicon). At low numbers of lesions per replicon, inhibition of replicon initiation was the predominant response; at higher numbers of lesions per replicon, blockage of chain growth was also observed. After irradiation with a dose that initially blocked chain growth, the rate at which cells recovered their ability to synthesize increasingly more and larger size DNA was a function both of replicon size and of excision repair capacity. Cells with small replicons recovered more rapidly than cells with large replicons, and excision repair-deficient cells recovered less rapidly than excision-competent cells. These observations indicate that excision repair capacity and replicon size play major roles in the response of DNA replication to ultraviolet damage.

Effects of 3-aminobenzamide on DNA synthesis and cell cycle progression in Chinese hamster ovary cells.

3-Aminobenzamide (3AB), an inhibitor of poly(ADP-ribose) polymerase, is a potent inducer of sister chromatid exchanges (SCEs). Because of the possible relation between SCEs and DNA synthesis, the effects of 3AB on DNA synthesis and cell cycle progression in Chinese hamster ovary (CHO) cells were examined. Unlike all other SCE-inducing agents whose effects on DNA synthesis have been studied, short term exposures (30-120 min) of 3AB did not inhibit the overall rate of DNA synthesis and this result was independent of the amount of bromodeoxyuridine (BrdU) in the DNA. Longer exposure times (greater than 24 h) did result in an extended S phase, but this was not due to an effect on the rate of DNA chain elongation. 3AB also delayed the entry of cells into S phase. The overall cell cycle delay was dose dependent, approaching 9 h after a 54 h exposure to 10 mM 3AB. Earlier reports that 3AB is neither mutagenic nor cytotoxic were confirmed. Thus 3AB acts to increase SCE frequency by a mechanism distinct from that which causes cytotoxicity and mutagenicity, and does not involve any inhibition in the rate of DNA chain growth.

Critical Steps for Induction of Chromosomal Aberrations in CHO Cells Heated in S Phase

The following four effects on DNA replication are observed in cells heated in S phase of the cell cycle: (1) inhibition of replicon initiation, (2) delay in DNA chain elongation into multicluster-sized molecules > 160S, (3) reduction in fork displacement rate, and (4) increase in single-stranded regions in replicating DNA. Since cells heated in S phase manifest chromosomal aberrations when they enter metaphase, whereas cells heated in G1 do not, we attempted to determine if the effects on DNA replication are critical for the induction of chromosomal aberrations by studying these same effects during DNA replication when synchronous CHO cells had been heated (10 min at 45.5 degrees C) in G1 phase. Following a heat-induced G1 block (12 h), we found previously that when the cells entered S phase, replicon initiation was functional and chain elongation into multicluster-sized molecules > 160S was delayed but completed during S phase. In the present study, we find that the fork displacement rate was near normal and that there was no increase in single-stranded DNA. Additionally, an increase in excess nuclear protein induced in the heated G1-phase cells returns to a normal level by about 12 h, just prior to when the cells enter S phase. Since the excess nuclear protein remains for many hours in heated S-phase cells, we hypothesize that the excess nuclear protein is responsible for the drastic reduction in the fork displacement rate and the associated increase in single-stranded DNA. Furthermore, we hypothesize that this persistent increase in single-stranded DNA during replication is a critical step for the induction of chromosomal aberrations in heated S-phase cells. Consistent with this hypothesis, we observed that aphidicolin (1-2 micrograms/ml) treatment of S-phase cells for 13-16 h, which results in a twofold increase in single-stranded DNA during the inhibition of DNA synthesis, also induces chromosomal aberrations. Possibly, endogenous endonucleolytic attack occurs opposite these sites of single-stranded DNA, thus creating double-strand breaks which either can remain unrepaired or are misrepaired to account for the chromatid breaks and exchanges, respectively, observed as cells complete their cell cycle and enter metaphase.

Multiple thymidine incorporation peaks in the S phase of synchronous human diploid fibroblasts

Abstract Synchronous populations of human diploid fibroblasts, CHO cells, and HeLa cells were obtained by mitotic selection. Human diploid fibroblasts were found to have three distinct peaks of thymidine incorporation during a 10–13 h S phase. This contrasts with CHO and HeLa which have one (or, for CHO, occasionally 2) peak(s) of thymidine incorporation during a 6–8 h S phase.

A cytogenetic investigation of DNA rereplication after hydroxyurea treatment: implications for gene amplification

Although the mechanisms leading to gene amplification are poorly understood, it has recently been proposed that the initial event of amplification is the rereplication of a variable, but relatively large, amount of the genome within a single cell cycle. We sought evidence for rereplication of DNA as a basis for gene amplification through two cytogenetic techniques: differential staining for sister-chromatid exchange analysis and premature chromosome condensation. Synchronized Chinese hamster ovary cells were incubated continuously with bromodeoxyuridine and treated with hydroxyurea (HU) when cells were approximately 2 h into the S phase. After 6 h exposure to HU, the drug was removed and at 3 h intervals thereafter metaphase cells were collected and the chromosomes were stained by the fluorescence-plus-Giemsa procedure. No staining patterns consistent with rereplication of DNA were observed. Since HU causes cytogenetic damage, the premature chromosome condensation technique was used to determine the kinetics of chromosome damage after removal of HU. Extensive G2 chromosome damage within 1 h after removal of HU from the medium was found, although cesium chloride gradient analysis showed that there was no rereplication of DNA during this time. Contrary to a previous report, these results provide no evidence that incubation of cells with HU during S phase induces rereplication of DNA within a single cell cycle. The results observed are consistent with the hypothesis that drug-induced aberrations and the subsequent abnormal segregation of chromosomal fragments are the first steps in the process that leads to gene amplification in drug-treated mammalian cells.

DNA fork displacement rates in Bloom's syndrome fibroblasts

Abstract DNA fork displacement rates were measured in three lines of Blooms syndrome cells and in a normal diploid fibroblast line. Fork displacement rates in Blooms cells were approx. 55–65% of the rate in normal fibroblasts.

Replicon sizes in non-transformed and SV40-transformed cells, as estimated by a bromodeoxyuridine photolysis method

Abstract Replicon sizes were measured in Simian Virus 40 (SV40)-transformed and untransformed normal human, xeroderma pigmentosum (XP), and mouse 3T3 cells with an X-ray plus bromodeoxyuridine (BUdR) photolysis method. Replicon sizes in SV40-transformed cells were at least twice those in untransformed counterparts, but DNA fork displacement rates were only slightly increased.

DNA fork displacement rates in synchronous aneuploid and diploid mammalian cells.

DNA fork displacement rates were measured in Chinese hamster ovary cells (CHO), human HeLa cells and human diploid fibroblasts. For CHO cells two independent techniques were used: one based on CsCl equilibrium density gradients and the other on 313 nm photolysis of incorporated bromodeoxyuridine (BrdUrd). Both methods indicated that there was no significant variation in fork displacement rates in CHO cells as they progressed through S phase. Asynchronous CHO cultures displayed the same average value (1.0 micron/min) and range of values as found in synchronous cells. In contrast, the rate of DNA fork displacement in HeLa cells, measured by the BrdUrd-313 nm method, increased continuously from 0.8 micron/min in early S to 2.5 micron/min in late S. For human diploid fibroblasts, in early S, the rate was approximately 0.7 micron/min and decreased to a minimum of 0.5 micron/min in mid S. The replication fork displacement rate then increased to a maximum of 0.9 micron/min in late S and declined again before the end of S phase. This pattern of DNA fork displacement rates roughly paralleled the overall thymidine incorporation rate and appears quite different from the patterns found for HeLa and CHO cells.