The effect of delay on flap survival in an irradiated field

Chronic radiation skin injury without ulceration was induced in rats by administering either 3000 or 5000 rads in staged doses. Either 4 or 8 months later, McFarlane et al. dorsal flaps were elevated, with half being delayed and half non-delayed. Measurements showed that flap survival in irradiated skin was significantly increased by delay [approximately two of four experimental groups (4 months, 5000 rads; and 8 months, 3000 rads)]; flap survival was increased with borderline significance in a third experimental group (8 months, 5000 rads). These data indicate that flap survival can be increased by delay in an irradiated field. The presence of the vascular delay phenomenon suggests that microvascular occlusion alone cannot account for radiation-induced complications in skin.     

Assay of radiation effects in mouse skin as expressed in wound healing

The effect of 150 kVp X irradiation on the healing of full depth surgical wounds in the lower dorsal skin of the mouse was assayed by measuring the wound strength of seven 2-mm-wide segments along each wound. The strength of unirradiated wounds increased with time in two phases: during the first 2 weeks it reached nearly half of the values recorded from unwounded skin, after which the rate of increase slowed for at least 2 weeks before beginning a second increase. By 150 days, the breaking strength of the wound was about 80% of that of unwounded skin. A single dose of 18 Gy prior to wounding reduced the strength of the wounds to about one-third to one-half that of an unirradiated wounds within the 3 months of follow-up. The effect of irradiation on wound strength did not change as the interval between exposure and wounding was increased to 2 months but decreased slightly when this interval was extended to 3 months. When the healing wound was irradiated within 5 days of surgery, the effect on healing was about the same as with preirradiation; if irradiation was delayed for 12 days after wounding the second phase of healing was only postponed and the wound strength ultimately approached the values recorded from unirradiated wounds. The wound strength of skin preirradiated by X rays and assayed 14 days after wounding showed a clear sigmoid dose response with a threshold between 8 and 10 Gy and a plateau at the maximum effect above 20 Gy. The persistence for at least 3 months of the effect of radiation on wound healing suggests that the tissues involved in the healing process are normally proliferating slowly. The accelerated expression of radiation injury through surgical wounding permits the early quantification of the radiation response of tissues that would normally be delayed in their expression of radiation damage.     

Growth regulation in X-irradiated mouse skin; the possible role of chalones.

Extracts of hairless mouse skin were tested for their content of epidermal G1 inhibitor and G2 inhibitor at daily intervals after X-irradiation with 4 500 or 2 250 rad. After either dose the skin extracts lacked G1 inhibitory activity on days 5 and 6 respectively after irradiation. This coincided with the time when the epidermal mitotic rate again became normal and started a period of over-shoot. The time interval of 5-6 days corresponds to the turnover time of the differentiating cells in hairless mouse back epidermis. The findings indicate that the proliferating cells in epidermis can respond to changes in local chalone concentration, even after X-irradiation at the tested doses, and that the irradiated epidermal cell population still retains some important properties inherent in a cybernetically regulated system. The local G2-inhibitory activity also varied after irradiation, but these variations could not be directly related to the corresponding mitotic rates.     

THE EFFECT OF A MEDIUM DOSE (430 ROENTGENS) OF X-RAY IRRADIATION ON RESTING CELLS OF THE LIVER

The mitotic activity of regenerating liver cells after a single dose (430 r) of x-ray irradiation was studied. In every group of the experimental animals (white rats), the mitotic activity (mitotic index) and the number of abnormal mitotic figures were determined. The results indicated that resting cells irradiated a short time before mitotic activity showed reactions similar to those of cells irradiated during mitotic activity. The disturbances in the irradiated mitotically active cells were only quantitatively different from those in the irradiated resting cells. The disturbances in the irradiated resting cells depended upon the time interval between the irradiation and the beginning of mitotic activity stimulated by partial hepatectomy. It was found that the shorter the time interval, the more pronounced were the disturbances and the more similar they became to those of irradiated mitotically active cells. Conversely, the longer the time interval between the irradiation and the beginning of mitotic activity, the less pronounced were the disturbances and the more similar they became to those of the non-irradiated control cells. A discussion is presented as to whether or not the lesions of resting cells caused by a single medium dose of x-ray irradiation are reversible, and whether such lesions are only brought to light by the process of mitosis or whether the process of mitosis renders it possible for these lesions to develop.     

Some effects of X-irradiation on the activity of the thyroid and pituitary glands of Xenopus laevis (Amphibia) during metamorphosis

A histological study of irradiated thyroid and pituitary glands of metamorphosing Xenopus tadpoles was made. Both glands shrink, reaching a minimum nine hours after irradiation and recover by 24 hours. It is suggested that sudden release of hormones may explain a reported hastening of metamorphosis in irradiated tadpoles.  

Summary:

Xenopus larvae received 2500 rads of whole body X-rays.
Nine hours after irradiation both pituitary and thyroid volumes were significantly less than the controls. From 24 hours after, the volumes had returned to control levels.
The mitotic incidence in irradiated thyroids fell within five hours to one tenth of the control value and remained suppressed for at least three days.     

Pleiotropic effects of heterozygosity at the mating-type locus of the yeast Saccharomyces cerevisiae on repair, recombination and transformation

Sexual (MAT a/) and sexual (MAT a/a) strains of the yeast Saccharomyces cerevisiae, which are completely isogenic except at the MAT locus, were compared in their response to ultraviolet radiation. The effects of UV on survival, mitotic intragenic recombination, photoreactivation, and transformation efficiency with UV-irradiated plasmid DNA were examined. The sexual strain had enhanced survival and higher rates of mitotic intragenic recombination compared with the asexual strain. Exposure to visible light subsequent to irradiation increased the survival of both sexual and asexual strains, and decreased their rates of mitotic intragenic recombination. Similar results were obtained by Haladus and Zuk (1980) in their examination of sexual strains homozygous for rad6-1, and wild-type sexuals.

Our sexual strain was also consistently more proficient at transforming plasmid DNA, whether that DNA had been irradiated or not. When pre-irradiated with 25 J/m² of UV, MAT a/ cells transformed more efficiently than MAT a/a cells. When subsequently exposed to light, the ability of these pre-irradiated cells to transform decreased for both strains with increasing irradiation of the plasmid. A smaller decrease in transformation efficiency occurred when cells of both strains were kept in the dark.

When pre-irradiated with 100 J/m², the MAT a/ cells showed a 2-fold increase in their transformation efficiency of both irradiated and unirradiated plasmids by up to 2-fold, a phenomenon not seen in the MAT a/a cells even when pre-irradiated with much higher doses of UV. This increase in transformation efficiency was not, however, seen in the MAT a/ cells when they were exposed to visible light after UV irradiation. These results suggest that cells with the MAT a genotype have a UV-inducible system that increases the efficiency of transformation in the absence of visible light. This increase in transformation is not an induced increase in the repair of plasmid DNA, but rather an increase in the ability of pre-irradiated MAT a/ cells to take up exogenous DNA. MAT a/a cells do not appear to have a similarity inducible system. To the best of our knowledge, this phenomenon has not been previously reported.     

Effects of radiation on host-tumor interactions using the multicellular tumor spheroid model

Summary Use of the multicellular tumor spheroid as a tumor model allows separate host or tumor treatment with ionizing radiation and examination of the effects on host-tumor immune interactions. Spheroids of EMT6/Ro, a BALB/c mammary tumor were implanted into the peritoneal cavity of syngeneic immunized mice, recovered, and dissociated into single cells. Cytolytic activity of mature spheroid associated cells and peritoneal cells was resistant to radiation doses as high as 1000 rads when irradiated directly prior to assay. Mice irradiated (200, 400, 700 rads) 24 h prior to spheroid injection had an increased number of tumor cells and decreased number of tumor infiltrating and peritoneal host cells upon spheroid recovery. This was paralleled by an increased colony forming efficiency per spheroid. Cytolytic activity of the spheroid associated cells against radiolabeled EMT6 cells was in many cases decreased with radiation although lysis was the same on a per cell basis. Cytolytic activity by peritoneal cells from these mice increased with dose as measured on a per cell basis. This activity from irradiated animals was carried out by a Thyl⁺ cell.     

Time-Lapse Cinemicrographic Studies of X-Irradiated HeLa S3 Cells: I. Cell Progression and Cell Disintegration

Time-lapse cinemicrographs of synchronous HeLa S3 cells irradiated with 220 kv X-rays at various stages of interphase provided data for constructing pedigrees, measuring the duration of both generation cycles and mitoses, and scoring events associated with cell disintegration for up to seven postirradiation generations. The onset of the first mitosis after doses of 500 rads was delayed as expected from previous studies of the age dependence of “mitotic delay.” The interval between this first mitosis and the next was indistinguishable from that for unirradiated control cells, while the subsequent two generations were again prolonged, on the average, though not so severely as was the irradiated generation. The duration of mitosis was increased proportionally more than interphase. Cell disintegration took place by way of two morphologically distinct processes. In three-quarters of the cases the cells were rounded and apparently trapped in metaphase when they disintegrated; the remaining disintegrations occurred in spread, interphase cells. In cells disintegrating from the rounded configuration, the generation preceding disintegration was prolonged relative to that in cells which divided; in cells disintegrating from either configuration, the penultimate generation was also prolonged. The mitotic times were disproportionately increased in both of these generations. It is suggested that in this system X-ray damage is preferentially expressed as derangement of the mitotic process; such damage ultimately brings about permanent mitotic arrest in the majority of cells.     

Developmental changes of the proliferative response of mouse epidermal melanocytes to skin wounding

A cut was made on the middorsal skin of mice of various ages of strain C57BL/0J using fine iridectomy scissors. Specimens from the wounded skins were fixed at various days after wounding and were subjected to the dopa reaction and to the combined dopa-premelanin reaction. When the dorsal skins of 1.5-day-old mice were wounded, the melanocyte population positive to the dopa reaction as well as the melanoblast-melanocyte population positive to the combined dopa-premelanin reaction increased dramatically in the epidermis adjacent to a skin wound. Pigment-producing melanocytes in mitosis were frequently found in the vicinity of a wound immediately after wounding. When the dorsal skins of 4.5-day-old mice were wounded, the increase in the melanocyte and melanoblast-melanocyte populations was smaller than that of 1.5-day-old mice. The increase in number of pigment-producing melanocytes in mitosis was reduced and delayed as compared to 1.5-day-old mice. When the dorsal skins of 8.5-, 20.5-, and 60.5-day-old mice were wounded, the increase in the melanocyte and melanoblast-melanocyte populations was much smaller than the newborn mice. Moreover, pigment-producing melanocytes in mitosis were never found. These results indicate that the proliferative response of mouse epidermal melanocytes to skin wounding becomes delayed and diminished with development.     

The RBE for skin tumors and hair follicle damage in the rat following irradiation with alpha particles and electrons

Rat skin was irradiated with cyclotron-accelerated alpha particles with doses ranging from 210 rads to 6850 rads and monoenergetic electrons with doses ranging from 810 rads to 12,300 rads. The beams were modified so that the depth-dose curves were approximately identical with penetrations of about 1.0 mm. Tumors were counted every 4 weeks for 80 weeks, and at death or sacrifice the hair follicle damage was assessed by using "whole mounts" of separated epithelium. The RBE values determined from a comparison of the dose response curves were: acute skin injury, RBE = 3.0+/-1.0; hair follicle survival, RBE = 2.1 +/- 0.7; hair follicle damage, RBE = 2.6 = 0.4; tumor induction, RBE = 2.9+/- 0.5. Within the experimental error, these values were independent of the dose. For both types of radiation, the tumor incidence increased approximately as the square of time and at low doses approximately as the 4th power of dose. The histological characteristics of the tumors and the correlation between the incidence of tumors and damaged hair follicles were independent of the type of radiation. The results were consistent with the hypothesis that structural damage to the hair follicles is a factor in the tumor induction process.     

Effect of fibroblast implants on wound healing of irradiated skin: assay of wound strength and quantitative immunohistology of collagen

The role of dermal fibroblasts in the expression of radiation-induced damage to the skin was studied. Fibroblasts from neonatal mice were cultured, harvested, and injected into full-depth surgical incisions in the dorsal area of mouse skin, which had been previously locally irradiated by 18 Gy X rays. As a control, cells irradiated with a dose of 20 Gy were also injected. The effect of radiation and fibroblast implants on the gain of skin wound strength was assayed. In an additional experiment freshly isolated cells were implanted. Two weeks following wounding the irradiated skin had reached only about a third of the strength of unirradiated skin. A significant increase of wound strength in irradiated skin was observed when 1.5-2 x 10(6) cultured fibroblasts or freshly isolated fibroblasts were injected into the 20-mm-long wound bed. Irradiated cells had significantly less effect. This suggests that implanting isolated syngeneic cells may "rescue" wounds from the effect of prior irradiation. Semiquantitative immunohistology of types I and III collagen was performed in parallel using a video image digitizing system. Levels of both types I and III collagen were altered in the dermis and the wound tissues in irradiated skin, but the implant of cultured fibroblasts did not affect notably the total levels and the disposition of the two collagen isotypes.     

Cell proliferation in EMT6 tumors treated with single doses of x-rays or hydroxyurea. I. Experimental results

EMT6 mouse mammary tumors were treated in vivo with 5 mg/mouse of hydroxyurea (HU) or 300 rads of X-rays. The proliferation of the tumor cells was followed for 28 hr after treatment. Changes in the 3H-TdR labeling index, the mitotic index, the specific activity of the 3H-TdR-labeled DNA, and the proportion of suspended, clonogenic cells in the S phase of the cell cycle were examined and compared. Evidence was found for reassortment of the surviving cells in treated tumors into partially synchronous cohorts. The partial synchrony in the proliferation of the surviving cells was not accurately predicted by the changes in the labeling index and the mitotic index. The changes in DNA specific activity proved unacceptable as an indicator of cell proliferation in solid EMT6 tumors treated with low doses of radiation or HU.     

Effects of ionizing radiation (60Co gamma rays) on growth and morphogenesis ofHaworthia mirabilis,haw. Callus tissue

Summary The effects of γ-radiation on growth and morphogenesis ofHaworthia callus in vitro were determined. The doses ranged from 100 to 5000 rads. Survival, growth pattern, growth rate, and differentiation of vegetative buds and roots in both irradiated and nonirradiated callus were compared. Growth data up to 24 weeks for irradiated and control cultures were analyzed. The dose range between 800 to 2500 rads produced compact callus as compared to the controls which were friable. After 12 weeks all control cultures differentiated vegetative buds with roots, whereas callus exposed to 800 to 2500 rads continued to grow with little or no organogenesis. However, it was observed that the wet and dry weights of callus receiving 1000 to 1500 rads ultimately exceeded those of nonirradiated controls.     

Immunoreactivity to antinucleoside antibodies in X-irradiated HeLa cells

Synchronized HeLa cells were stained with antibodies to purine and pyrimidine nucleosides by immunofluorescent and immunoperoxidase techniques. These antibodies react only with denatured or single-stranded regions of DNA. Nuclear attachment of antibody was seen only during the period of DNA synthesis as determined by ³H-thymidine incorporation. Positive nuclear immunoreactivity was seen in approx. 15% of cells obtained by mitotic selection at a time corresponding to the G 1 phase. After exposure to ionizing radiation, 80% of the G 1 cells were reactive. Induction of immunoreactivity was dose dependent over the range of 100 to 1 000 rads. Treatment of irradiated G 1 cells with deoxyribonuclease completely eliminated the positive nuclear reaction. Exposure to ribonuclease had no effect. Incubation of the G 1 cells for 90 min at 37 or 0–4 °C after the administration of 1 000 rads resulted in a prompt decrease of immunoreactivity to control levels. However, in the presence of 0.04 μg/ml actinomycin D, positive nuclear staining remained at high levels. No such effect could be observed as a result of exposure to cytosine arabinoside or hydroxyurea. It is concluded that X-irradiation of G 1 HeLa cells produces single-stranded regions in nuclear DNA that can be detected by anti-pyrimidine and anti-purine antibodies.     

Lack of Mitotic Delays at the Onset of Proliferation in Dormant Root Primordia Challenged by Ionizing Radiation

X-rays at doses between 2.5 and 20 Gy were applied to Allium cepa L. bulbs containing either dormant root primordia (before water imbibition) or actively proliferating meristems. Irradiation of the primordia that were enriched in G₀ cells neither delayed proliferation onset nor root sprouting. Under both protocols, irradiation decreased the final length of the roots to about 60 % (at 20 Gy) of that reached by the unirradiated controls. Irradiation of the proliferating meristems increased the mitotic index at some fixation times. This could not be due to a rise in the cell entry into mitosis, as the rate of root growth decreased simultaneously. The increased mitotic index should be the consequence of a delay in the relative time taken by mitosis in the whole cycle time. Lengthened mitosis probably allows the post-replicative repair of most DNA lesions, as the frequency of interphases with micronuclei was higher in the cells which were irradiated when still dormant than in those irradiated when cycling. Thus, the mitotic delays should be the consequence of a checkpoint pathway activated by the presence of DNA damage. This feedback mechanism seems only to develop after cell proliferation is restored. This revised version was published online in July 2006 with corrections to the Cover Date.     

Chinese hamster ovary cell mitosis and its response to ionizing radiation: a morphological analysis of the living cell

Repeated microscopic observations of exponentially growing Chinese hamster ovary cells were made and the times and mitotic stages were recorded in control and irradiated cultures at 37 degrees C. As determined by autoradiography, the time from the end of S phase to early prophase (the G2 phase) was 46 min, to breakdown of the nuclear envelope was 91 min, and to restoration of the nuclear envelope was 116 min. The time spent in morphologically distinguishable phases of mitosis and the effects of 0.5, 1.0, 1.5, 2.0, and 4.0 Gy of gamma or X radiation on cells at each phase were determined. Affected cells were found to be delayed without or with reversion to an earlier mitotic stage before recovering and advancing through mitosis. Cells were timed in the five steps comprising delay with reversion: inertia, cessation I, regression, cessation II, and reprogression. No cells treated in late prophase, i.e., within 8-10 min of nuclear envelope breakdown, were delayed by the doses used; therefore the critical or transition point must be situated in middle prophase. Cells irradiated in this stage were not delayed by 0.5 or 1.0 Gy, but suffered a dose-dependent delay with or without reversion after 1.5, 2.0, and 4.0 Gy. Cells irradiated in early prophase and very late interphase responded similarly, but a greater percentage of the latter reverted.     

Cell Proliferation In Emt6 Tumors Treated With Single Doses of X-Rays Or Hydroxyurea. I. Experimental Results

EMT6 mouse mammary tumors were treated in vivo with 5 mg/mouse of hydroxyurea (HU) or 300 rads of X-rays. the proliferation of the tumor cells was followed for 28 hr after treatment. Changes in the ³H-TdR labeling index, the mitotic index, the specific activity of the ³H-TdR-labeled DNA, and the proportion of suspended, clonogenic cells in the S phase of the cell cycle were examined and compared. Evidence was found for reassortment of the surviving cells in treated tumors into partially synchronous cohorts. the partial synchrony in the proliferation of the surviving cells was not accurately predicted by the changes in the labeling index and the mitotic index. the changes in DNA specific activity proved unacceptable as an indicator of cell proliferation in solid EMT6 tumors treated with low doses of radiation or HU.     

Ultraviolet Light-Induced Division Delay in Synchronized Chinese Hamster Cells

The age-dependent, ultraviolet light (UVL) (254 nm)-induced division delay of surviving and nonsurviving Chinese hamster cells was studied. The response was examined after UVL exposures adjusted to yield approximately the same survival levels at different stages of the cell cycle, 60% or 30% survival. Cells irradiated in the middle of S suffered the longest division delay, and cells exposed in mitosis or in G₁ had about the same smaller delay in division. Cells irradiated in G₂, however, were not delayed at either survival level. It was further established, after exposures that yielded about 30% survivors at various stages of the cycle, that surviving cells had shorter delays than nonsurvivors. This difference was not observed for cells in G₂ at the time of exposure; i.e., neither surviving nor nonsurviving G₂ cells were delayed in division. The examination of mitotic index vs. time revealed that most cells reach mitosis, but all of the increase in the number of cells in the population can be accounted for by the increase of the viable cell fraction. These observations suggest strongly that nonsurviving cells, although present during most of the experiment, are stopped at mitosis and do not divide. Cells in mitosis at the time of irradiation complete their division, and in the same length of time as unirradiated controls. Division and mitotic delays after UVL are relatively much larger than after X-ray doses that reduce survival to about the same level.     

A radiation-induced inhibitor of chromosome condensation and nuclear envelope breakdown in HeLa cells.

An in vitro microscopic assay for mitosis-inducing activity in mitotic HeLa cells was developed and used to demonstrate that cells irradiated and arrested in G2 phase of the cell cycle contain an inhibitor of mitosis. This assay system has a number of advantages over other assays including the use of autologous components (HeLa nuclei and mitotic cell extracts) in contrast to the microinjection method with Xenopus oocytes and without the requirements for microinjection expertise and Xenopus oocytes. The radiation-inducible inhibitor was detected at the lowest radiation dose tested (2 Gy) with maximal activity achieved within 30 min after radiation. Inhibitor activity decayed with time after radiation (2 Gy) with no activity detected at 6 h even though the cells remained in G2 phase, suggesting that either synthesis or activation of additional components is necessary for recovery from G2 arrest. The inhibitor activity was not detected in irradiated cells treated with caffeine to induce premature recovery from G2 arrest.     

Enhanced mitotic activity induced by irradiation is abolished by PGI2 pretreatment

It is well known that irradiation may induce pronounced vascular lesions. Experimental studies revealed that irradiation induces an increased mitotic activity. As PGI2 has been claimed to be an antilesional agent, we wondered whether a pretreatment with PGI2 might abolish some of the effects induced by irradiation. 2 Groups of 24 rabbits were studied. 8 Rabbits each were irradiated with either 5 or 10 Gy on an abdominal aortic segment; 8 animals were sham treated. In each of the 3 groups half of the animals (n = 4) received PGI2 and half the buffer vehicle only. It is demonstrated that PGI2 is able to depress the enhanced mitotic activity induced by irradiation. In comparison to the controls, vascular thromboxane formation is decreased, the temporary increase in PGI2-formation by the vessel wall is less pronounced, whereas the conversion of exogenous arachidonic acid is unchanged. It is hypothetized that stable PGI2-analogues given during irradiation may probably prevent at least in part radiation-induced vascular changes and finally radiation-induced vasculopathy; this claim has to be proven in human.