Bradley W. Lyons

Variation in Radiation-Induced Formation of DNA Double-Strand Breaks as a Function of Chromatin Structure

The influence of chromatin structure on induction of DNA double-strand breaks (DSBs) by X radiation was studied in DNA from CHO cells. Whole cells, nuclei with condensed or relaxed chromatin, and deproteinized DNA in agarose plugs were irradiated and DSB formation was measured as a decrease in the length of DNA by nondenaturing, pulsed-field, agarose gel electrophoresis. The yield of DSBs in deproteinized DNA (2.3 x 10(-10) DSBs Da-1 Gy-1) was observed to be 70 times greater than the yield of DSBs (3.1 x 10(-12) DSBs Da-1 Gy-1) observed in DNA in the intact cell nucleus. Organization of DNA into the basic nucleosome repeat structure and condensation of the chromatin fiber into higher-order structure protected DNA from DSB induction by factors of 8.3 and 4.5, respectively. An additional twofold protection of DNA in fully condensed chromatin occurred in the intact cell nucleus. Since this protection did not appear to involve chromatin structure, we speculate that this additional protection may result from the association of soluble protein and nonprotein sulfhydryls with DNA in the intact cell nucleus. The results are consistent with the organization of nuclear DNA into both basic nucleosome repeat structure and higher-order chromatin structure providing significant protection against DSB induction.

Detection of Ionizing Radiation-Induced DNA Double-Strand Breaks by Filter Elution Is Affected by Nuclear Chromatin Structure

Chinese hamster ovary cells were irradiated with 250 kVp X rays and analyzed for the presence of DNA double-strand breaks using either polycarbonate filter elution or pulsed-field agarose gel electrophoresis at neutral pH. Reduction in DNA length detected by filter elution was produced as a nonlinear function of increasing radiation dose, with a quasi-threshold at low total dose, and as a first-order function of increasing radiation dose as detected by gel electrophoresis. The quasi-threshold observed with filter elution was eliminated when nuclei were isolated from irradiated cells and their chromatin relaxed in a buffer containing low-molarity monovalent cation prior to analysis by filter elution. The results suggest either that the chemical structure of the DNA double-strand breaks produced by low-LET radiation necessitates a DNA relaxation step before they can be detected accurately by filter elution, or that at low total radiation dose a DNA complex forms on the polycarbonate filter.

Alterations in the Nuclear Matrix Protein Mass Correlate with Heat-induced Inhibition of DNA Single-strand-break Repair

The total protein mass co-isolating with the nuclear matrix or nucleoid from Chinese hamster ovary (CHO) cells was observed to increase in heated cells as a function of increasing exposure temperature between 43 degrees C and 45 degrees C or of exposure time at any temperature. The sedimentation distance of the CHO cell nucleoid in sucrose gradients increased with increasing exposure time at 45 degrees C. Both these nuclear alterations correlated in a log-linear manner with heat-induced inhibition of DNA strand break repair. A two-fold threshold increase in nuclear matrix protein mass preceded any substantial inhibition of repair of DNA single-strand breaks. When preheated cells (45 degrees C for 15 min) were incubated at 37 degrees C the nuclear matrix protein mass and nucleoid sedimentation recovered with a half-time of about 5 h, while DNA single-strand-break repair recovered with a half-time of about 2 h. When preheated cells were placed at 41 degrees C (step-down heating; SDH) a further increase was observed in the nuclear matrix protein mass and the half-time of DNA strand break repair, while nucleoid sedimentation recovered toward control values. These results implicate alterations in the protein mass of the nuclear matrix in heat-induced inhibition of repair of DNA single-strand breaks.

Inhibition of Repair of Radiation-induced DNA Damage by Thermal Shock in Chinese Hamster Ovary Cells

The effect of exposure to elevated temperatures (41-45 degrees C) on the repair of radiation-induced DNA strand breaks was measured in monolayer cultured Chinese hamster ovary (CHO) cells. Prior exposure of cells to temperatures between 43 and 45 degrees C resulted in significant decreases in the rate of repair of DNA damage. Exposure to 45 degrees C for 15 min slowed the rate of DNA repair to 0.17 of the control repair rate. The To for inactivation of DNA repair was observed to be 34, 13 and 6 min at 43, 44 and 45 degrees C, respectively. Stepdown-heating (45 degrees C for 15 min followed by repair at 41 degrees C) resulted in greater inhibition of DNA repair (0.11 of the control rate) than was observed after acute heating alone. Repair at 41 degrees C was observed to proceed in unheated cells at a faster rate than at 37 degrees C. An Arrhenius analysis of the inactivation kinetics of DNA repair between 43 and 45 degrees C indicated an activation energy of 140 kcal mol-1 of protein for the inhibition of DNA repair. In general, the results were inconsistent with either a retardation of the DNA repair rate or an increase in unrepaired DNA lesions being responsible for heat-induced radiosensitization.

Topoisomerase activity in irradiated mammalian cells

The role of topoisomerase enzymes in the response of HeLa S3 cells to ionizing radiation was investigated. Exposure of cells to 100 Gy of X-radiation had no detectable effect either on the total cellular topoisomerase activity as measured by the relaxation of supercoiled plasmid DNA by cell sonicates or on the total cellular topoisomerase II activity as measured by plasmid DNA catenation. Total topoisomerase II activity remained constant for up to 90 min after cell irradiation. The effect of 2 drugs (caffeine and novobiocin) which inhibit topoisomerase II activity on the HeLa cell response to radiation was determined. Both drugs were found to inhibit topoisomerase II in vitro and to inhibit the recovery of nucleoid sedimentation in irradiated cells in vivo to the same extent. Topoisomerase II was inhibited by 50% by exposure to 10 mM caffeine and 0.79 mM novobiocin. At low concentrations neither drug affected the induction frequency, nor the rejoining rate, of DNA double-strand breaks. Caffeine (5 mM) inhibited the short-term recovery of cells from radiation while novobiocin (0.79 mM) had no detectable effect on the capacity of cells to recover from radiation exposure. The results indicate that topoisomerase II is not required for DNA double-strand break rejoining though it could be required for the recovery of DNA coiling in the irradiated cell. If topoisomerase II is involved at all in cell recovery from irradiation, this role does not apparently involve an ATP-dependent enzyme activity.

Induction of DNA strand breaks in transcriptionally active DNA sequences of mouse cells by low doses of ionizing radiation.

The efficiency of DNA single-strand break induction was measured in transcriptionally active DNA, transcriptionally inert satellite DNA, and bulk DNA sequences of mouse L929 cells using the alkaline filter elution assay. The cells were exposed to increasing doses of X-radiation up to 1000 rad. DNA which either eluted from or was retained on polycarbonate filters during the assays was collected onto nitrocellulose filters and hybridized against radiolabeled poly(A+)RNA (to probe transcribing DNA sequences) or mouse satellite DNA. The increasing rate and extent of elution of bulk DNA or specific DNA sequences after increasing radiation doses was taken as a measure of the increased frequency of radiation-induced DNA strand breaks. The results indicate that a significant fraction of transcriptionally active DNA contains endogenous strand breaks. With increasing dose, the efficiency of radiation-induced DNA strand breakage in bulk, transcriptionally active and satellite DNA sequences was observed to be the same when the sum of all eluted DNA was considered. However, the early eluting fractions contained DNA which was enriched in active sequences. Since DNA elutes as a function of size, the early fractions contain smaller DNA than later fractions. Therefore, our results indicate that the fraction of active sequences which elutes early resides on smaller fragments on the average than the later eluting DNA, and that even low doses of radiation preferentially cause breaks in regions of DNA containing active sequences.

DNA damage repair in quiescent murine mammary carcinoma cells in culture.

Murine mammary carcinoma cells (line 67) were grown in unfed cultures for up to 9 days. In cultures (day 2-3) in which cells were proliferatively active and in day 3-5 (transition) cells, a large fraction of nuclear DNA was retained on polycarbonate filters when assayed by the alkaline filter elution technique. In contrast, the fraction of DNA retained on filters was significantly reduced for nonproliferating (Q, quiescent) cells from unfed 7-9 day cultures. The increase in endogenous DNA breaks followed both the decrease in proliferative state and clonogenicity in these cells. When day 7 Q cells were refed these endogenous DNA breaks were removed with a half-time of about 2.5 h. When the cells were exposed to X-irradiation and the integrity of their nuclear DNA measured by the alkaline filter elution assay, as much as a 2-fold greater frequency of radiation-induced DNA breaks was produced in Q versus P cells. DNA breaks were also removed from irradiated Q cells at a rate which was 0.23 that observed in P cells. We suggest that the depressed capacity for DNA damage removal in Q cells is responsible for their greater radiosensitivity, and the impaired DNA damage repair is probably due to a reduced level of energy sources in these unfed Q cell cultures.

Topoisomerase II activity in a DNA double-strand break repair deficient Chinese hamster ovary cell line

Topoisomerase II activity was measured in wild-type, Chinese hamster ovary K1 cells, and in the DNA double-strand break repair deficient xrs-6 cell line. Total topoisomerase II activity in a high salt, nuclear extract was found to be the same in both cell lines, as measured by decatenation of kinetoplast DNA networks and catenation of plasmid pBR322 DNA. While at low drug concentrations m-AMSA-induced enzyme cutting of nuclear DNA was 25% less in xrs-6 cells, the frequency of DNA breaks at high concentrations of the drug, and thus the frequency of the topoisomerase II enzyme, was the same in both cell lines. Despite the presence of equivalent enzyme levels in both cell lines, the xrs-6 cell line was 3 times more sensitive to drug-induced cytotoxicity. These results may be due to the fact that, as with X-radiation-induced DNA damage, xrs-6 cells are deficient in the capacity to rejoin topoisomerase II-induced DNA double-strand breaks.

DNA-damage processing in a radiation-sensitive mouse cell line

The induction and repair of radiation-induced DNA damage was assessed in 3 mouse cell lines, including the parental L cell line, a radiation-sensitive, SL3-147 mutant cell line and the H5 revertant to radiation resistance. The yield of neither radiation-induced DNA single- nor double-strand breaks could explain the variable sensitivity of the 3 cell lines. Closure of DNA single-strand breaks proceeded at a similar rate in both the L and SL3-147 cell lines. Closure of DNA double-strand breaks however was significantly slower and less complete in the SL3-147 cell line than in either of the radiation-resistant cell lines. The results are consistent with the increased radiation sensitivity of the SL3-147 cell line resulting from a defect in their ability to repair radiation-induced DNA double-strand breaks.

Production of milligram concentrations of free prostate specific antigen (fPSA) from LNCaP cell culture: difference between fPSA from LNCaP cell and seminal plasma.

We have established a procedure for the production of milligrams of free PSA (fPSA) from LNCaP cells derived from a human carcinoma of the prostate. By growing LNCaP cells in a serum‐free medium in the presence of a synthetic androgen (R1881) and taking advantage of the special design of the Micro‐mouse Hollow Fiber Bioreactor, relatively pure fPSA could be obtained. We found that columns containing either Sephacryl S‐100 or S‐200 could be used to remove the small amount of bovine serum albumin (BSA) and PSA‐α1‐antichymotrypsin complex (PSA‐ACT) from the preparation. More than 90% of the PSA from LNCaP cell cultures are fPSA. Like fPSA from seminal plasma, two fractions of fPSA differing in protease activity can be separated by DEAE‐Sepharose chromatography. Based on the band pattern exhibited on the Western blot following sodium dodecyl sulfate‐polyacrylamide electrophoresis separation, fPSA from LNCaP contains more inactive PSA isoforms. This was confirmed by chromatofocusing: the isoelectric point (pI) of the major PSA isoforms from the LNCaP cell culture were higher (6.8 and 6.6) than that (6.4 and 6.1) of fPSA from seminal fluid. We conclude that the LNCaP cell culture is a reliable source for obtaining large quantities of pure fPSA both for the preparation of assay calibrators and controls and for studying the difference in fPSA between benign prostate disease and prostate cancer. J. Clin. Lab. Anal. 12:6–13, 1998.