Relationships between DNA damage and the survival of murine bone marrow cells irradiated in situ

The relationships between DNA damage and the survival of murine bone marrow cells irradiated in situ were examined. Cell survival was assayed by the ability of bone marrow cells from irradiated mice to form colonies in vitro (CFU-C). DNA double-strand breaks (DSBs) were measured by neutral (nondenaturing) filter elution and pulsed-field gel electrophoresis (PFGE). Double-strand breaks were measured in the proliferating bone marrow cells, identified by injecting the mice with [3H]dThd at various times before gamma irradiation, as a model of the behavior of the radiosensitive target cells. To assess how the DNA lesions measured using these techniques correlated with cell killing, the effect of the radioprotective agent WR-2721 on the induction of DSBs in proliferating bone marrow cells was compared with its effect on CFU-C survival. WR-2721 protected against the killing of both granulocyte-macrophage and erythroid burst-forming CFU-C by a factor of about 2. In contrast, little (1.2-fold) protection was observed in the PFGE assay at radiation doses between 5 and 20 Gy. Similarly, at the lowest dose studied (5 Gy) there was little protection against DSBs as measured by neutral elution; only after doses of between 10 and 30 Gy was significant protection observed. Thus the previously reported predictive relationship between DSBs and cell survival in vitro does not appear to extend directly to murine bone marrow cells irradiated in vivo.

Simultaneous cytokinetic measurement of aneuploid tumors and associated diploid cells following continuous labelling with chlorodeoxyuridine

Cells from a murine tumor, MCa-K, were continuously labelled with the thymidine analogue chlorodeoxyuridine (CldUrd) and analyzed by bivariate flow cytometry in order to measure the growth fraction (GF) and potential doubling time (Tpot) of both the DNA-aneuploid tumor cells and the associated DNA-diploid cells. MCa-K has a DNA index of 1.7, rendering two, partially overlapping, populations observable with labelled and unlabelled cells in each population. The data from these tumors may be divided into three regions of differing DNA content, with one region containing a pure DNA-diploid population, a second region with both cell types, and a third region including only DNA-aneuploid cells. Equations are presented to characterize the fractions of labelled cells in each region as a function of labelling time and cell type, thereby permitting estimation of the proliferative properties of the populations. These equations include the possibility that DNA-aneuploid cells cease cycling both in G1 and in S phase to account for the observed numbers of unlabelled cells with S phase contents. The estimated value of Tpot of the DNA-diploid cells is 126.0 h with a GF of 42%, while that of the DNA-aneuploid cells is 36.9 h with a GF of 69%. It is also estimated that between 2% and 6% of all DNA-aneuploid cells starting DNA synthesis cease cycling, leading to 25% of the cells having an S-phase DNA content being noncycling.

Near-diploidy: a new prognostic factor for clinically localized prostate cancer treated with external beam radiation therapy

BACKGROUND

DNA ploidy is a significant prognostic factor in patients with prostate cancer. Using DNA/nuclear protein flow cytometry, a subpopulation of tumors with near-diploid DNA is identifiable. The prognostic significance of near-diploidy was examined.

METHODS

Paraffin-embedded formalin fixed prostate tumor tissue from patients treated at M. D. Anderson Cancer Center with external beam radiation therapy was processed for DNA/nuclear protein flow cytometry. All patients had pretreatment and follow-up serum prostate specific antigen (PSA) levels. Seventy-six specimens were suitable for flow cytometric analysis. Tumors were classified as either diploid (n = 30), near-diploid (n = 24), or nondiploid (n = 22, tetraploid and aneuploid). Median follow-up time was 36 months.

RESULTS

Diploid tumors were associated with a significantly better actuarial outcome at 4 years, compared with near-diploid tumors, using either biochemical relapse (rising PSA) or a composite end point of a rising PSA or clinical relapse (16% versus 52% relapse, P < 0.05, log-rank). Moreover, patients who had nondiploid tumors had the worst prognosis (77% relapse, composite end point). No significant difference was observed between diploid and near-diploid neoplasms regarding actuarial local control, freedom from metastasis, freedom from clinical relapse, or overall survival time. A Cox proportional hazards model, using the composite end point of a rising PSA or relapse, was performed with ploidy categorized as diploid, near-diploid, and nondiploid; pretreatment PSA, DNA ploidy, and tumor grade were found to be independent prognostic factors. When ploidy was categorized as diploid or near-diploid (nondiploid tumors excluded), pretreatment serum PSA and DNA ploidy were independent predictors of outcome. Ploidy remained an independent prognostic factor even when nondiploid tumors were excluded.

CONCLUSIONS

These data show that patients who have near-diploid tumors have an intermediate prognosis between the more favorable diploid tumors and the less favorable nondiploid tumors.

The prognostic significance of DNA ploidy in clinically localized prostate cancer treated with radiation therapy

PURPOSE

To determine the prognostic significance of deoxyribonucleic acid (DNA) ploidy in comparison to pretreatment prostate specific antigen (PSA) and other prognostic factors for patients with adenocarcinoma of the prostate treated with external beam radiotherapy.

METHODS AND MATERIALS

Paraffin-embedded prostatic adenocarcinoma material was obtained from patients treated from 1987-1991. Sufficient histologic material for flow cytometric DNA content analysis was obtained from 86 patients and adequate histograms were obtained from 76 of these. The DNA histogram profiles were classified as diploid, tetraploid, or aneuploid. Median patient follow-up was 36 months.

RESULTS

There were 54 patients with diploid tumors, and 22 with nondiploid tumors (11 tetraploid and 11 aneuploid). Since the disease outcome for tetraploid and aneuploid tumors was the same, these were pooled (nondiploid tumors). The distribution of diploidy and nondiploidy correlated with pretreatment PSA (p < 0.0005) and grade (p = 0.055), but not with stage, pretreatment prostatic acid phosphatase, transurethral resection, pretreatment serum testosterone, or age. In actuarial univariate analyses, DNA ploidy was a significant predictor of outcome for local failure, distant metastases, any clinical relapse, rising PSA, and rising PSA and/or relapse. Ploidy was not a significant predictor of overall survival, although there were only six deaths. Diploidy predicted for improved outcome, for example, 34.6% incidence of a rising PSA and/or relapse at 4 years compared to 76.9% with nondiploidy (p < 0.0001). An actuarial univariate analysis of other potential prognostic factors using the composite endpoint of rising PSA and/or relapse also revealed pretreatment PSA, grade, pretreatment prostatic acid phosphatase, stage, and serum testosterone to be significant predictors of outcome. In Cox proportional hazards analysis, pretreatment PSA, DNA ploidy, and grade were the only independent prognostic factors for disease outcome using the composite endpoint.

CONCLUSION

DNA ploidy is an independent predictor of outcome in patients with Stages T1-T3 prostate cancer treated with definitive external beam radiotherapy.

Double labelling to obtain S phase subpopulations: application to determine cell kinetics of diploid cells in an aneuploid tumour

We studied the cell kinetics of the murine mammary carcinoma MCa-K using iododeoxyuridine (IdUrd) and chlorodeoxyuridine (CldUrd) given at different times as independently detectable labels of S phase cells. The presence of IdUrd and CldUrd, and the amount of DNA were measured by three-colour flow cytometry making it possible to define three subpopulations within S phase and to measure the progression through the cell cycle during the time following labelling. In DNA histograms of these subpopulations, the diploid and aneuploid cells (which had a DNA index of 1.7) are essentially completely separated. From appropriate combinations of cells labelled with IdUrd only, CldUrd only, or both, it was possible to construct separate DNA distributions for the labelled diploid and aneuploid cells at the times of administration of each label. The kinetics of the diploid and aneuploid cells could be calculated for individual tumours from these two time points without having to make corrections for the presence of the second population. The diploid and aneuploid populations had indistinguishable S and G2 + M phase durations, T(S) and T(G2 + M), of about 9 and 2 h; however, the potential doubling time values for the aneuploid and diploid populations were 30.2 and 101.2 h respectively.

Hormonal protection from procarbazine-induced testicular damage is selective for survival and recovery of stem spermatogonia

Procarbazine produces long-term sterility in the male by killing stem spermatogonia. The degree and selectivity of protection of stem spermatogonia in rats from procarbazine by pretreatment with steroid hormones were investigated. Male LBNF1 rats were treated for 6 weeks with Silastic implants containing testosterone plus 17 beta-estradiol. The hormone-treated rats and sham-treated controls were given a single injection of graded doses of procarbazine and the hormone implants were removed the next day. Spermatogonial stem cell survival and function, assessed by the repopulation indices and sperm head counts 10 weeks later, showed that stem spermatogonia were protected by testosterone plus 17 beta-estradiol treatment from the toxic effects of procarbazine with a dose-modifying protection factor of about 2.5. In contrast, there was no hormonal protection from the procarbazine-induced killing of differentiating spermatogonia, preleptotene spermatocytes, and spermatocytes in meiotic prophase or from the delay in maturation of round spermatids, assessed 9 days after procarbazine injection by histological or flow cytometric methods. In addition, there was no hormonal protection from the procarbazine-induced decline in body weights and lymphocyte counts, indicating that the gastrointestinal, neurological, and hematological systems were not protected. The specificity of protection indicates that the hormonal protection of the stem spermatogonia is not the result of a systemic or overall testicular decrease in drug delivery, decrease in bioactivation, nor increase in drug detoxification, except possibly within the stem cells themselves. We conclude that the degree of hormonal protection and its specificity would be appropriate for clinical application provided that the mechanism of protection is elucidated and appears applicable to humans.

Proliferation kinetics of recruited cells in a mouse mammary carcinoma

Solid tumors contain populations of proliferating (P) and quiescent (Q) cells. Shifting between these populations occurs continuously and cells are recruited from quiescence to proliferate (Q-->P) as a result of exogenously applied or endogenous cell depleting stimuli. Direct measurements of the proliferation kinetics of these Q-->P cells in solid tumors are difficult to make because of the much larger percentage of P-cells. In order to specifically analyze the kinetics of the Q-->P cells, double thymidine analogue labeling was used. This was accomplished by first labeling in vivo all of the P-cells in MCaK tumors using continuous exposure to chlorodeoxyuridine (CldUrd) administered by a minipump over 21 h. About 75% of the aneuploid cells are P-cells based on CldUrd labeling. At different times after the pumps were removed, the tumors were pulse-labeled with iododeoxyuridine (IdUrd) and harvested 6 h later. A 3-color flow cytometry assay was used to simultaneously and independently analyze CldUrd and IdUrd incorporation, as well as DNA content. The Q-->P cells were identified as having only been labeled with IdUrd. The length of their S-phase was calculated from the movement of the Q-->P cells during the 6 h after IdUrd labeling. The results showed the length of S-phase for the recruited cells to be slightly, but significantly, longer than the length of S-phase for the total cells (11 h versus 9 h, respectively). Thus, the recruited cells appear to have slightly slower kinetics than the proliferating cells in the absence of a perturbing stimulus such as radiotherapy or chemotherapy.

Calculating potential doubling time using monoclonal antibodies specific for two halogenated thymidine analogues

PURPOSE

A new flow cytometric technique that allows for two-incorporated thymidine analogues to be measured simultaneously and independently has been used to improve the accuracy of in vivo cell kinetic estimates, i.e., the length of S-phase (TS) and potential doubling time (Tpot).

METHODS AND MATERIALS

The analogues chlorodeoxyuridine and iododeoxyuridine were injected at different times into mice bearing the mouse mammary tumor MCaK. At different times after labeling, the tumors were harvested and prepared for three color flow cytometric analysis of DNA, chlorodeoxyuridine, and iododeoxyuridine. Control experiments showed that similar estimates of Tpot were obtained from each label when administered singly, or as staggered pulses. Comparisons were made between TS and Tpot calculated from a single label (single point), from the averaged result of the two labels from the same tumor (two point-ave), and from the simultaneous nonlinear fitting of the measured parameters from the two labels, from the same tumor (two point-fit). These estimates of TS and Tpot were then compared to reference values obtained by fitting the pooled measured parameters from all the tumors, that were labeled for different periods of time.

RESULTS

While all of the methods resulted in similar mean estimates of TS and Tpot that were close to the reference values, the fewest assumptions, and the least variability in the results, were obtained using the two point-fit data.

CONCLUSION

The estimation of Tpot using two thymidine analogues is more accurate than that obtained from a single label.

Influence of intracellular thiol and polyamine levels on radioprotection by aminothiols

We examined the effect of manipulating the levels of two endogenous radioprotectors, glutathione (GSH) and polyamines, on the ability of exogenous aminothiols to protect Chinese hamster ovary cells from the lethal effects of gamma-radiation. Treatment with 0.5 mmol dm-3 buthionine sulfoximine (BSO) for 24 h depleted GSH levels to < 1% of control and significantly sensitized the cells to irradiation in air. Undepleted control cells were protected by WR-1065 (4 mmol dm-3; 30-min preirradiation treatment at 37 degrees C) by 2.09-fold (range 1.98-2.21) at the 10% survival level, whereas BSO-treated cells were protected by a factor of 1.98 (range 1.95-2.14) at this survival level. Thus, GSH depletion had no significant effect on the radioprotective capacity of WR-1065. Treating cells with 1 mmol dm-3 alpha-difluoromethyl ornithine (DFMO) for 48 h depleted the polyamines putrescine and spermidine to very low levels, while spermine was not significantly depleted. DFMO also sensitized cells to aerobic irradiation. WR-1065 protected DFMO-treated cells by 2.29-fold (range 2.08-2.53), whereas undepleted control cells were protected by 2.09-fold (range 1.98-2.21) at the 10% survival level. Thus, WR-1065 appeared to offset the radiosensitizing effect of the DFMO treatment. Cysteamine, on the other hand, protected control and DFMO-treated cells to the same extent. We also examined the effect of combinations of exogenous thiols on radiosensitivity. Cells were treated with WR-1065 (4 mmol dm-3) for 30 min and then with increasing concentrations of dithiothreitol for 5 min prior to irradiation. The protective effects of these two thiols were simply additive.

Recognition and reduction of artifacts from autolysis in paraffin-embedded tissue using DNA/nuclear protein flow cytometry

Artifacts from autolysis can be a problem in retrospective flow-cytometric analyses of DNA content in paraffin-embedded tissues. Autolyzed tissue from rat liver, human liver, and rat spleen were stained for DNA and nuclear protein to determine if this technique would be useful in identifying partially degraded cells. After the tissue was deparaffinized and rehydrated, the nuclei were isolated using 0.5% pepsin. Propidium iodide (PI) and fluorescein isothiocyanate (FITC) were used to stain DNA and nuclear protein. When unfixed rat liver tissue was allowed to undergo autolysis at 4 degrees C for 24-48 h before fixation, there was a progressive broadening of the G1 and G2M DNA peaks and a slight increase in the average DNA contents of these peaks. Nuclei that stained more intensely with PI also stained more intensely with FITC. Similar results were obtained using human liver and rat spleen. Sometimes the increased PI staining resulted in a false aneuploid peak. The distinctive skewing of the DNA/nuclear protein histograms from autolysis was reduced by increasing the incubation of the tissue in 0.5% pepsin from 0.5 h to 1.5 h during the nuclei-isolation step. The DNA/nuclear protein method provides a means for identifying artifacts from autolysis, whereas the extended pepsin treatment provides a means for reducing these artifacts.

Flow cytometric analysis of two incorporated halogenated thymidine analogues and DNA in a mouse mammary tumor grown in vivo

A technique was developed for the staining of nuclei for DNA using propidium iodide, and incorporated chlorodeoxyuridine (CldUrd) and iododeoxyuridine (IdUrd) using two monoclonal antibodies that showed negligible cross-reactivity. The mouse mammary solid tumor MCaK was labeled in vivo by intraperitoneal injection of the nucleosides. Tumor cell nuclei were stained after isolation from ethanol-fixed solid tumor tissue and acid denaturation. The Br3 antibody, which specifically recognizes CldUrd, was applied first, followed by indirect staining with goat anti-mouse phycoerythrin. The direct fluorescein isothiocyanate conjugate of the B44 antibody, which specifically recognizes IdUrd, was then applied. In the direct conjugate form this antibody reacted only minimally with CldUrd. The nuclei were then stained with propidium iodide. With this dye combination the coefficients of variations of the DNA histograms were consistently in the 2-4% range. Two other dye combinations were compared. The propidium iodide/phycoerythrin/fluorescein isothiocyanate dye combination was the simplest because of the compatibility with single laser flow cytometry.

A quantitative method for evaluating bivariate flow cytometric data obtained using monoclonal antibodies to bromodeoxyuridine

A method is presented for analyzing data from bivariate analysis of cell populations exposed to bromodeoxyuridine and subsequently examined both for the presence of BrdUrd and for the cellular DNA content. It is shown that certain features may be defined in the bivariate data which are constant independent both of cell type and, within limits, experimental variability. These landmark features include the ratio of red, DNA, fluorescence of G2 + M cells to G1 cells, the ratio of green fluorescence corresponding to the non-specific binding of unlabeled G2 + M cells to unlabeled G1 cells, and the distribution of green fluorescence in unlabeled cells. The landmarks make it possible to standardize rules for establishing the separation line between-labeled and unlabeled cells as required in these experiments to obtain estimates of cytokinetic parameters. Values obtained for the DNA synthesis time and the potential doubling time which result from different decision rules for distinguishing labeled from unlabeled are compared in two murine tumor lines. The potential doubling time, but not the DNA synthesis time is shown to depend sensitively on the separation line. Suggestions are presented for analyzing clinical data with this procedure.

Measuring cell proliferation by relative movement. I. Introduction and in vitro studies

This paper presents two new ways of analysing data which may be obtained from pulse labelling a population of cells with bromodeoxyuridine and analysing that population as a function of time with bivariate flow cytometry. The progression of cells is measured by the change in position in the cell cycle, as shown by a change in the mean DNA content of the labelled and unlabelled cells. The particular measures of the mean DNA content used are extensions of the relative movement of the labelled undivided cells, RMlu(t), which was introduced by Begg and co-workers to measure the DNA synthesis time, TS. In general, the relative movement is defined as the mean DNA fluorescence of a population of cells less the DNA fluorescence of the cells in G1 and divided by the difference in DNA fluorescence of the cells in G2 + M and G1. In this paper we examine the relative movements of all the labelled cells and all of the unlabelled cells, denoted RML(t) and RMU(t) respectively. It is found that RML(t) and RMU(t) exhibit clear cyclic behaviour and distinguishable characteristics which depend directly on the transit times (T) of the cell cycle phases, i.e. TG1, TS and TG2 + M. Furthermore, the peak heights of the RMU(t) curve are shown to depend strongly on the growth fraction of the population under consideration. A theoretical treatment of the curves so obtained is presented, and is shown to yield values in close agreement with those from other methods for measuring these transit times and a lower limit to values for the growth fraction of Chinese hamster ovary cells grown in vitro.

Molecular genetic evidence for a differentiation-proliferation coupling during DMSO-induced myeloid maturation of HL-60 cells: role of the transcription elongation block in the c-myc gene

Proliferation-differentiation coupling was studied during dimethyl sulfoxide (DMSO)-induced myeloid maturation of HL-60 cells using transcription of the myeloperoxidase (MPO) and c-myc genes as indicators of differentiation and proliferation, respectively. Concomitant cell cycle kinetic analysis correlated the proliferation and transcription patterns. Transcription, cell cycle phases and rate of DNA synthesis were examined for up to 5 days of induction and, at 1-day intervals, analyzed during a 24-h reculture without the inducer. DMSO suppressed transcription of the c-myc and MPO genes with a t1/2 of 16 min and 7 h, respectively. The ability to recover transcription following reculture diminished with the progression of the induction and ultimately was lost; concomitantly, the cells irreversibly lost the capacity to divide. This indicated that the differentiation and proliferation processes are inseparable and that terminal differentiation accompanies irreversible proliferation arrest in HL-60 cells. We also studied the kinetics of the block to transcription elongation at the exon 1-intron 1 boundary of the c-myc gene. This block produces a 0.38 kb truncated transcript that is constitutively expressed in somatic cells (Re et al., Oncogene 5, 1247, 1990). During induction the level of the 0.38 kb RNA increased, while that of the complete c-myc mRNA decreased, indicating that this truncated RNA is generated instead of message through a monotonously initiated transcriptional process. Transcription initiation and synthesis of the 0.3 kb RNA persisted in terminally differentiated cells, suggesting a role for this RNA in non-proliferating cells.

Evaluation of flow cytometric methods for determining population potential doubling times using cultured cells

Various methods have been proposed for determining the potential doubling times (Tpot) of mammalian cell populations by using flow cytometric techniques after labeling the cells with bromodeoxyuridine (BrdUrd). We show here that, in a well-defined in vitro system where multiple time measurements are possible, all the methods give similar results that are close to the true population doubling time. Of ultimate interest, however, is the accuracy of determination of Tpot from a single time point. In this paper we compare the accuracy and precision of the methods in making such determinations at different times after labeling. The relative movement (RM) of BrdUrd-labeled cells that have not divided at the time of assay allows for computation of the length of S phase (Ts). The precision of estimation of Ts was enhanced when a quantity, v (a function of the fraction of BrdUrd-labeled divided and the fraction of BrdUrd-labeled undivided cells), was used to estimate the initial intercept of RM. Furthermore, calculation of Tpot from the formula, Tpot = ln(2) Ts/v, gave values closest to the observed population doubling time. It is suggested that the use of RM with v be the analytical method of choice for the calculation of Tpot from single time-point observations, preferably made at times between the length of the G2 and M phases (TG2M) and Ts.

Measuring potential doubling times of murine tumors using flow cytometry

Flow cytometric analysis of bromodeoxyuridine (BrdUrd) labeled cells has led to the description of various methods for determining population potential doubling times (Tpot) from samples obtained at a single time point. There have been several reports of results from human tumor samples using these various methods of analysis, but little documentation of the validity of these approaches in experimental tumor models. Recently, we reported results using in vitro cell cultures and determined the most reliable method for these. In this paper we report the results of this methodology when applied to two in vivo murine tumor models (MCaK and FSA). The analytic approach tested is summarized as follows: The relative movement (RMlu(t], a measure of the mean DNA fluorescence of BrdUrd-labeled cells that have not undergone division at the time of sampling, and a quantity v, a function of the fractions of BrdUrd-labeled divided and undivided cells, were measured for a series of time points following labeling. From each value of RMlu(t) an estimate of the length of S-phase (TS) was computed and from each v and TS a value for Tpot was found. These results were compared to the values of TS and Tpot obtained by fitting all the values simultaneously. Tumor MCaK values of TS and Tpot of 9.6 and 28.0 h were obtained from fitting all of the data. Tumor FSA gave values of 16.8 and 42.3 h for TS and Tpot, respectively. The results of this analysis show that single time point measurements can give reliable estimates of TS and Tpot.

New methods for calculating kinetic properties of cells in vitro using pulse labelling with bromodeoxyuridine

The transit times of Chinese hamster ovary cells through the phases of their cell cycle were measured using dual parameter flow cytometry to measure DNA content and the presence of monoclonal antibodies to bromodeoxyuridine. Up to four separate populations can be accurately measured: unlabelled cells in G2 + M; labelled cells that have not yet divided; labelled cells that have already divided; and the unlabelled cells that were originally in G1 plus the cells that were originally in G2 + M and have since divided. The fractions of cells in these populations can be easily followed in time and the usual kinetic properties can be estimated from these fractions, or combinations thereof, including the times through G1, S, G2 + M and the cycle time. We present equations for analysing this type of data and comment on which equations are most appropriate for measuring specific kinetic properties of the cells.

The accuracy of fine needle aspiration biopsy for flow cytometric determination of tumor DNA content

The use of fine needle aspiration (FNA) to obtain a diagnosis of malignancy is established in the practice of oncology, but there is little information on its accuracy in sampling tumor DNA content. We therefore compared flow cytometric DNA data obtained from FNA-derived samples with that obtained after digestion of the same murine tumor from which the aspirates had been taken. Fifteen female C3Hf/Kam mice were implanted with MCA-29 tumor cells from the same source tumor. MCA-29 is a multiploid mammary adenocarcinoma with two aneuploid populations (DNA Index of A = 1.67, B = 1.89). The tumors were grown to a mean size of 8.6 mm. After sacrifice, three FNAs were performed on each tumor, following which the whole tumor (WT) was excised and homogenized. All FNA and WT samples were digested with 0.04% pepsin and the nuclei stained with propidium iodide in preparation for flow cytometry. DNA histograms of the aspirates were compared with the corresponding WT histograms. Any single FNA detected population A in all (100%) cases and detected the less prominent population B in 94.3% of instances. Any single FNA was able to detect the same populations that were present in the whole tumor in 95.4% of cases, while the set of three aspirates matched the corresponding WT in 100% of cases. We conclude that FNA DNA histograms are accurate for the assessment of ploidy, but that in order to ensure detection of all tumor populations present, multiple aspirates are needed.

Effects of beta-all-trans retinoic acid on growth, proliferation, and cell death in a multicellular tumor spheroid model for squamous carcinomas

The growth of multicellular tumor spheroids, MTSs, from squamous carcinoma line MDA 886Ln was inhibited by beta-all-trans retinoic acid (RA). Inhibition occurred within 3 to 5 days of treatment, and MTS size then remained static for up to 2 weeks. Although their growth stopped, 10-day-treated MTSs incorporated [3H]thymidine into trichloroacetic acid-precipitable material, and the [3H]thymidine labeling index, determined by autoradiography, was equivalent between control and RA-treated MTSs. Bivariate flow cytometric analysis of bromodeoxyuridine-labeled MTSs showed equivalent S phase progression of labeled cells over an 8-hour chase. MTS growth stasis was not related to RA-induced cell cycle effects. Monitoring of MTSs for cell sloughing showed no significant cell shedding that could account for stasis. Quantitation of cell number and DNA content per MTS showed an RA-induced decrease. This was confirmed by histological analysis, which demonstrated the temporal appearance of acellular areas. MTS growth statis is thus related to an RA-induced cell loss in this MTS model for squamous carcinomas.

Comparative effect of the thiols dithiothreitol, cysteamine and WR-151326 on survival and on the induction of DNA damage in cultured Chinese hamster ovary cells exposed to gamma-radiation

We compared the ability of three thiols--dithiothreitol (DTT), cysteamine and WR-151326--to protect aerated Chinese hamster ovary cells from the lethal and DNA-damaging effects of gamma-radiation. These results were compared with earlier measurements for WR-1065 and WR-255591. The time-course and the concentration dependence of protection against cell killing was determined after 10 Gy of gamma-rays. The aminothiols cysteamine and WR-151326 protected at much lower extracellular concentrations than the simple thiol DTT; however, there was no clear difference between the behaviour of cysteamine, WR-151326, WR-1065 and WR-255591 in this respect. Protection by DTT and cysteamine was complete within 1 min, whereas for WR-151326, WR-1065 and WR-255591 about 30 min was required before protection began to reach a plateau. Based on these data, complete radiation survival curves were generated for each thiol and protection factors calculated. Effects on the induction of DNA single-strand breaks (ssb) and double-strand breaks (dsb) by gamma-rays were measured using alkaline (pH 12.1) and neutral (pH 7.0 and 9.6) elution, respectively. All three thiols protected against ssb induction, although to a significantly lower extent than against cell killing measured under identical conditions. Each thiol also protected against dsb induction. After high radiation doses the protection factors for dsb induction were also less than the protection factors for cell survival; however, when dsb were assayed using the low-dose replicate plating neutral elution method, the relative effect of each thiol on cell survival and on dsb induction appeared to be equivalent. The hierarchy of protection against both ssb and dsb induction (based on the extracellular thiol concentration required to produce a given degree of protection) was similar to that for cell survival, i.e., WR-151326 congruent to cysteamine less than DTT.

Improved method for computing potential doubling time from flow cytometric data

Relative movement methods use the timed progression of the mean fluorescence of cells which have been labeled with monoclonal antibodies against bromodeoxyuridine and displayed with bivariate flow cytometry according to DNA and label content to compute duration of DNA synthesis, TS. The relative movement is the difference of the mean DNA fluorescence of the labeled undivided cells from the G1 channel relative to the difference between the G1 and G2M channels. In this communication, we show how to extend this method to compute the potential doubling time, Tpot, the time required for a population of cells to double, given quiescent cells but no cell loss. A quantity v is introduced that is a function of the fraction of labeled divided cells and the fraction of labeled undivided cells. We show that v is independent of time and is equal to ln(2)Ts/Tpot so that Tpot (equal to ln(2)Ts/v) can be directly found from the information available in computing the relative movement. The method is applied to Chinese hamster ovary cells to demonstrate its utility.

The influence of bone marrow depletion on intestinal radiation damage

These experiments were designed to test the hypothesis that bone marrow damage contributes to lethality when the endpoint used is LD50 for gastrointestinal damage. Specific pathogen-free mice were irradiated to the total body, total abdomen, or to the total body followed by rescue with syngeneic bone marrow cells. The relationship between animal survival and jejunal crypt survival was also examined under these three experimental conditions. The LD50/10 after total abdominal irradiation (15.6 Gy) was higher than that for total body irradiation (11.4 Gy). Rescue with syngeneic bone marrow cells after total body irradiation also increased the LD50 10 days to 14.6 Gy. The proportion of animals surviving after total body irradiation depended on the number of bone marrow cells injected as a rescue inoculum. Hence gastrointestinal death after total body irradiation is influenced by bone marrow depletion. Crypt survival, however, was similar following all three experimental procedures. These data, therefore, demonstrate a dissociation between a clonogenic and lethality assay of intestinal damage. Furthermore, a comparison of crypt survival at the LD50 under the different conditions showed that a factor of 10 times more crypts were needed to rescue a mouse from gut lethality when the total body was irradiated than when only the total abdomen was treated. Hence, the concept of the intestinal "tissue rescuing unit" as a precise and constant number of crypts is inappropriate and will vary with the experimental conditions.

Time course of loss of residual radiation damage in murine skin assessed by retreatment

The amount of radiation damage remaining in mouse foot skin has been assessed by retreatment from 10 days to 6 months after a range of first doses. The acute skin reaction was used as the endpoint. Mice hind feet were first irradiated with a range of single doses (15-37.5 Gy) covering zero to near full effect. Feet were retreated with a full range of single doses together with groups of non-previously treated age-matched control mice. No age-related changes in radiation sensitivity were observed. Dose-response curves were constructed for all retreatment times for each priming dose, and isoeffect doses were calculated for both peak and average skin reactions. If 2-6 months were allowed to elapse before retreatment, the skin could be reirradiated as if it were previously untreated. However, if only 1 month was allowed to pass before retreatment, damage was 'remembered' after all first doses. The amount of damage 'remembered' in terms of dose was 11 Gy after a first dose of 37.5 Gy, and was less after the lower first doses.

Tissue repair and repopulation in the tumor bed effect

These experiments were designed to study the kinetics and magnitude of cell repair and repopulation in tissues whose damage results in the tumor bed effect. The right hind thighs of mice were irradiated with single doses or two equal gamma-ray fractions. Interfraction intervals ranging from 30 min to 24 h (to measure the kinetics of repair from sublethal damage) and 6 and 12 weeks (to determine the extent of repopulation) were used. One day after the second radiation dose 5 X 10(5) FSA tumor cells were inoculated into the center of the irradiated field. Radiation dose-response curves were obtained by calculating the time required for tumors to reach 12 mm diameter. No recovery occurred within 6 h of the radiation delivery as measured by this assay. Some recovery, 3.2-4.6 Gy above a single radiation dose, occurred when the interval between two fractions was 24 h. With increasing interfraction intervals of 6 and 12 weeks further dose sparing occurred in the amount of 5.0-6.9 and 7.5-8.3 Gy, respectively. The data suggest that repopulation is the major contributor to the radiation dose-sparing recovery of stromal tissue and that some proliferative response may occur as early as 1 day after the first irradiation.