Floyd M. Price

Cytogenetic response to G2-phase X irradiation in relation to DNA repair and radiosensitivity in a cancer-prone family with Li-Fraumeni syndrome

Noncancerous skin fibroblasts from six family members with Li-Fraumeni syndrome, five with cancer of diverse tissue origin and one with a premalignant neoplasm, showed a high frequency of chromatid aberrations, 94 to 119 breaks and 58 to 95 gaps per 100 metaphase cells arrested with colcemid 0.5 to 1.5 h after X irradiation (1.75 x 10(-2) C/kg). This response results from deficient repair of the radiation-induced DNA damage. In contrast, skin fibroblasts from two unrelated normal controls and a spouse showed 19 breaks and 17 to 19 gaps per 100 cells. Whereas all six members of the cancer-prone family had a radioresistant phenotype, only four had an inherited p53 mutation. Fibroblasts from a radioresistant family member showed the same extent of chromatid damage directly (0 to 0.5 h) after G2-phase X irradiation as those from the radiosensitive control spouse. We conclude, therefore, that radiosensitivity, as determined by cell killing in asynchronous populations of skin fibroblasts, is unrelated to chromosomal sensitivity to G2-phase X irradiation. However, the persistence of a high frequency of chromatid breaks and gaps at 0.5 to 1.5 h after G2-phase X irradiation, a manifestation of deficient DNA repair, is associated with proneness to cancer in this family.

Biochemical evidence for deficient DNA repair leading to enhanced G2 chromatid radiosensitivity and susceptibility to cancer

Human tumor cells and cells from cancer-prone individuals, compared with those from normal individuals, show a significantly higher incidence of chromatid breaks and gaps seen in metaphase cells immediately after G2 X irradiation. Previous studies with DNA repair-deficient mutants and DNA repair inhibitors strongly indicate that the enhancement results from a G2 deficiency(ies) in DNA repair. We report here biochemical evidence for a DNA repair deficiency that correlates with the cytogenetic studies. In the alkaline elution technique, after a pulse label with radioactive thymidine in the presence of 3-acetylaminobenzamide (a G2-phase blocker) and X irradiation, DNA from tumor or cancer-prone cells elutes more rapidly during the postirradiation period than that from normal cells. These results indicate that the DNA of tumor and cancer-prone cells either repairs more slowly or acquires more breaks than that of normal cells; breaks can accumulate during incomplete or deficient repair processes. The kinetic difference between normal and tumor or cancer-prone cells in DNA strand-break repair reaches a maximum within 2 h, and this maximum corresponds to the kinetic difference in chromatid aberration incidence following X irradiation reported previously. These findings support the concept that cells showing enhanced G2 chromatid radiosensitivity are deficient in DNA repair. The findings could also lead to a biochemical assay for cancer susceptibility.

A new culture medium for human skin epithelial cells

SummaryA new culture medium, NCTC 168, has been designed for human skin epithelial cells. This medium formulation was developed, by combining and testing at various concentrations, components of media NCTC 135 and 163, since a 1∶1 mixture of these two media with 10% horse serum supplement was found to promote epithelial cell outgrowth from human skin explants. The buffer system in NCTC 168 maintains the pH of the medium between 7.0 and 7.2. In contrast to other media tested, NCTC 168 with 10% horse serum is capable of initiating and sustaining larger epithelial cell outgrowths. Explants in serum-supplemented NCTC 168 in the absence of feeder cells reproducibly yield confluent epithelial cell sheets apparently free of fibroblasts after only 19 to 28 days as compared with 5 weeks or longer for the other media tested. NCTC 168 also supports passage of human epithelial cells to the sixth subculture generation without feeder cells. Electron microscopy has shown the presence of desmosomes and tonofilaments in the passaged cells indicating the epithelial nature of the cells. The addition of epithelial growth factor, hydrocortisone and insulin at 5 ng per ml, 4 μg per ml and 5 μg per ml, respectively did not appreciably enhance the growth of the epithelial cells.

Oxygen and light effects on chromosomal aberrations in mouse cells in vitro.

Abstract Decreasing the oxygen concentration in the gas phase from 18% (atmospheric) to 1% decreased the frequency of chromosomal aberrations in mass cultures of cells from adult lung and embryos of two inbred mouse strains. Both the rate of shift from the diploid number and the incidence of abnormal chromosomes were decreased at the lower oxygen level. Similarly, shielding mouse cells from room lights (cool white, fluorescent) during routine fluid renewals reduced the incidence of abnormal chromosomes, particularly minutes and metacentrics. The increased incidence of chromosomal abnormalities on exposure of cells to light and high oxygen presumably results from a photodynamic reaction affecting the DNA or associated proteins of the chromatin fibers.

Radiation-induced chromatid aberrations in Cockayne syndrome and xeroderma pigmentosum group C fibroblasts in relation to cancer predisposition

We showed previously that the persistence of chromatid breaks and gaps after G2 phase irradiation with X-rays or near-UV visible light characterizes skin fibroblasts from individuals with cancer-prone genetic diseases. This abnormal response appears to result from deficient DNA repair during G2 and to be associated with cancer proneness. We have, therefore, compared the responses of cells from two genetic disorders, Cockayne syndrome (CS) and xeroderma pigmentosum complementation group C(XP-C), both of which exhibit cellular hypersensitivity to sunlight, but only one of which, XP, manifests a high rate of sunlight-induced cancer. CS cells, in contrast to XP cells, showed a normal G2 response to irradiation with either X-rays or near-UV visible light. However, CS cells showed a deficiency in repair of DNA damage inflicted by light during S and G1 phases of the cell cycle. The present results support the concept that deficient DNA repair during G2 phase plays a role in carcinogenesis. This deficient repair in the presence of DNA damage and continuous cell cycling from activation of proto-oncogenes or loss of suppressor genes may be necessary and sufficient for cancer development.

X-ray-induced chromatid damage in cells from Down syndrome and alzheimer disease patients in relation to DNA repair and cancer proneness

Frequencies of chromatid aberrations in response to G2-phase x-irradiation were compared in PHA-stimulated blood lymphocytes from healthy control subjects, Down syndrome (DS) patients, and Alzheimer disease (AD) patients. In cells arrested with Colcemid immediately (0-30 min) after x-irradiation, DS, AD, and control cells showed similar high frequencies of chromatid breaks and gaps, representing unrepaired DNA strand breaks. Frequencies had decreased in AD and control cells arrested 30-90 min after irradiation. However, DS cells had two- to three-fold higher frequencies than AD or control cells. This result indicates deficient repair of the DNA damage in DS cells. Similar responses were obtained with lymphocytes from four of seven DS parents tested and with skin fibroblasts from DS patients compared to age-matched controls. Addition of 1-beta-D-arabinofuranosylcytosine (ara-C), an inhibitor of the repair polymerase, after x-irradiation during G2 phase increased the frequencies of chromatid breaks and gaps in lymphocytes from control and AD donors significantly more than in those from DS patients. This result indicates a deficiency in DS cells in incision at sites of x-ray-induced damage. Thus DS, like other cancer-prone genetic disorders, has a G2-phase DNA repair deficiency in strand break repair and also a second DNA repair deficiency in incision activity.

Cytogenetic responses to G2 phase X-irradiation of cells from retinoblastoma patients

Fibroblast cell lines from 20 retinoblastoma (RB) patients with the hereditary bilateral form of disease compared with 16 lines from normal donors had a significantly higher chromatid aberration frequency (CAF), and more displaced and nondisplaced breaks per 100 metaphase cells after x-irradiation during the G2 phase of the cell cycle. The mean CAF was 39 +/- 1.0, range 30-46, for cells from normal subjects, compared to a mean of 245.6, range 101-506, for cells from hereditary RB patients (p < 10(-6). Of fibroblast lines from eight patients with unilateral RB, four had a CAF comparable to that of lines from normal donors (< 60) and four had a high CAF (> 130), resembling that of hereditary forms; two of the latter four lines were from patients with familial or deletion 13 forms of RB. Furthermore, in two families, PHA-stimulated blood lymphocytes from RB patients, one bilateral and one unilateral, and from certain unaffected first-degree relatives after G2 phase X-irradiation had a high CAF (> or = 110) compared to a CAF (> or = 53) of cells from three normal donors sampled at the same time. These results were shown not to be related to differences in cell cycle progression or initial extent of chromatid damage. The results suggest that the high frequency of chromatid aberrations in the cells from hereditary RB patients results from a genetic deficiency in DNA repair.

Genes on chromosomes 1 and 4 in the mouse are associated with repair of radiation-induced chromatin damage

Early-passage skin fibroblasts from different inbred and congenic strains of mice were X-irradiated (1 Gy), and the number of chromatid breaks was determined at 2.0 h after irradiation. The cells from DBA/2N, C3H/HeN, STS/A, C57BL/6N, BALB/cJ, and AKR/N had 25 to 42 chromatid breaks per 100 metaphase cells (efficient repair phenotype). NZB/NJ had greater than 78 and BALB/cAn had 87 to 110 chromatid breaks per 100 cells (inefficient repair phenotype). Differences between BALB/cAn and BALB/c. DBA/2 congenic strains which carry less than 1% of the DBA/2 genome indicate that two genes, one on chromosome 1 linked to bcl-2-Pep-3 and the other on chromosome 4 closely linked to Fv-1, affect the efficiency with which the cells repair radiation-induced chromatin damage.

Serum-induced chromosome damage and neoplastic transformation of mouse cells in vitro

SummaryIn previous studies, mouse cells grown in medium supplemented with horse serum (HS) developed more chromosomal aberrations and underwent malignant transformation earlier than cells from the same pool grown with fetal bovine serum (FBS) supplement. In the present study cells derived from C3Hf/HeN mouse embryos were grown in medium NCTC-135 supplemented with various combinations of large- and small-molecule fractions of HS and FBS in an effort to determine the effective components. The results indicate that the large-molecule fraction of HS (mare or stallion) produces alterations in chromosome number and structure. HS is also shown to cause chromatid breaks and exchanges at or near the centromere in contrast to fluorescent-light-induced breaks which occur randomly along the chromatid. However, efforts to control completely chromosome stability and malignant transformation through the use of large-and small-molecule fractions of HS and FBS or combinations thereof were unsuccessful. In comnection with this study, diagnosis of malignant transformation in vitro was made by a direct sampling method based on cytologic criteria previously described and documented. With one exception, the diagnoses of 11 different cell lines were consistent with results of in vivo assays.

Effect of fractions of horse and fetal bovine serum on neoplastic conversion of C3H mouse cells in tissue culture

SummaryCultures derived from C3H/He mouse embryos were grown in medium NCTC 135 supplemented with horse serum, fetal bovine serum, or various combinations of large and small molecule fractions of horse and fetal bovine serum. Cultures in medium NCTC 135 alone or in medium 135 supplemented with the small molecule fraction of either horse or fetal bovine serum did not grow as continuous long term lines. The best growth was obtained when the cultures were in medium containing the large molecule fraction of fetal bovine serum either alone or in combination with a small molecule fraction. Cells grown in the presence of the low molecular weight fraction of horse serum invariably produced tumors on injection into syngeneic animals. Cells in the small molecular weight fraction of fetal bovine serum combined with the large molecular weight fraction of horse serum produced tumors after a prolonged period in vitro. *** DIRECT SUPPORT *** A00S8010 00003