Identification of novel susceptibility genes in ozone-induced inflammation in mice.

Ozone (O(3)) remains a prevalent air pollutant and public health concern. Inf2 is a significant quantitative trait locus on murine chromosome 17 that contributes to susceptibility to O(3)-induced infiltration of polymorphonuclear leukocytes (PMNs) into the lung, but the mechanisms of susceptibility remain unclear. The study objectives were to confirm and restrict Inf2, and to identify and test novel candidate susceptibility gene(s). Congenic strains of mice that contained overlapping regions of Inf2 and their controls, and mice deficient in either major histocompatibility complex (MHC) class II genes or the Tnf cluster, were exposed to air or O(3). Lung inflammation and gene expression were assessed. Inf2 was restricted from 16.42 Mbp to 0.96 Mbp, and bioinformatic analysis identified MHC class II, the Tnf cluster and other genes in this region that contain potentially informative single nucleotide polymorphisms between the susceptible and resistant mice. Furthermore, O(3)-induced inflammation was significantly reduced in mice deficient in MHC class II genes or the Tnf cluster genes, compared with wild-type controls. Gene expression differences were also observed in MHC class II and Tnf cluster genes. This integrative genetic analysis of Inf2 led to identification of novel O(3) susceptibility genes that may provide important, new therapeutic targets in susceptible individuals.

Correlation between lung fibrosis and radiation therapy dose after concurrent radiation therapy and chemotherapy for limited small cell lung cancer.

PURPOSE: To evaluate the relationship between physician-identified radiographic fibrosis, lung tissue physical density change, and radiation dose after concurrent radiation therapy and chemotherapy for limited small cell lung cancer. MATERIALS AND METHODS: Fibrosis volumes of different severity levels were delineated on computed tomography (CT) images obtained at 1-year follow-up of 21 patients with complete response to concurrent radiation therapy and chemotherapy for limited small cell lung carcinoma. Delivered treatments were reconstructed with a three-dimensional treatment planning system and geometrically registered to the follow-up CT images. Tissue physical density change and radiation dose were computed for each voxel within each fibrosis volume and within normal lung. Patient responses were grouped per radiation and chemotherapy protocol. RESULTS: A significant correlation was noted between fibrosis grade and tissue physical density change and fibrosis grade. For doses less than 30 Gy, the probability of observing fibrosis was less than 2% with conventional fractionation and less than 4% with accelerated fractionation. Physical lung density change also showed a threshold of 30-35 Gy. For doses of 30-55 Gy and cisplatin and etoposide (PE) chemotherapy, fibrosis probability was 2.0 times greater for accelerated fractionation compared with conventional fractionation (P < .005) and was correlated to increasing dose for both fractionation schedules. CONCLUSION: Lung tissue physical density changes correlated well with fibrosis incidence, and both increased with increasing dose greater than a threshold of 30-35 Gy. With concurrent PE chemotherapy, fibrosis probability was twice as great with accelerated fractionation as with once-daily fractionation.

Organizational response of normal tissues to irradiation.

A central tenet in the treatment of cancer patients with radiation has been that normal tissue complications were related to the volume of the tissue irradiated, although the mechanisms underlying this phenomenon were poorly understood. The advent of new treatment techniques, such as three-dimensional (3-D) conformal treatments, drove the developers of models to evaluate the resultant complex dose distribution plans, particularly in terms of predicting normal tissue complications. However, a lack of experimental data on the effects of changing volume on normal tissue responses made it difficult to substantiate these models. Consequently, radiobiology research on normal tissue dose volume effects in experimental animal models was initiated, providing considerable insight into the effect of changing volume on normal tissue response for a large number of tissues. This paper summarizes these data and the potential impact of new concepts and data in molecular radiation biology on dose volume effects in normal tissues.

Overexpression of manganese superoxide dismutase (MnSOD) in whole lung or alveolar type II cells of MnSOD transgenic mice does not provide intrinsic lung irradiation protection.

Intratracheal (IT) injection of the transgene for human manganese superoxide dismutase in plasmid/liposome (SOD2-PL) complex prior to irradiation protects C57BL/6J mice from whole lung irradiation-induced organizing alveolitis/fibrosis. Transgene mRNA was detected in alveolar type II (AT-II) and tracheobronchial tree cells explanted to culture 48 hours after gene therapy. To determine whether constitutive overexpression of murine MnSOD (Sod2) in whole lung or surfactant promoter-restricted AT-II cells (SP1)-SOD2 mice would provide intrinsic radioresistance, transgenic mice of two strains were compared with age-matched controls. Other groups of surfactant promoter-restricted (SP1)-SOD2 transgenic mice or control FeVB/NHsd mice received IT SOD2-PL gene therapy prior to irradiation. There was no significant intrinsic lung protection in either strain of MnSOD transgenic mice. The SP1-SOD2 transgenic mice were protected from lung damage by IT injection of the human SOD2-PL complex 24 hours prior to irradiation. Thus, overexpression of either human SOD2 or murine Sod2 in the lungs of transgenic mice does not provide intrinsic lung irradiation protection. The overexpression of SOD2 in the SP1-SOD2 mice may have made the mice more sensitive to irradiation.

In-field and out-of-field effects in partial volume lung irradiation in rodents: possible correlation between early dna damage and functional endpoints.

PURPOSE: Recent observations have shown that there are regional variations in radiation response in mouse lung as measured by functional assays. Furthermore, there are both in-field and out-of-field effects in radiation-induced lung damage as observed by DNA assay in rats. The purpose of this work is: (a) to examine mice lethality data following partial volume lung irradiation to assess the possibility of directional or regional effects, (b) to evaluate the correlation between mice lethality data and DNA damage assayed by micronuclei production in rat lung, and (c) to re-interpret mice lethality considering the existence of directional effects in lung cellular response to partial volume irradiation. METHODS AND MATERIALS: The lethality data for mice, generated at the M. D. Anderson Cancer Center, Houston, and micronuclei yield data for rats obtained at Princess Margaret Hospital, Toronto, were used. A radiobiological model that allows for out-of-field and in-field effects for lung cell damage and lung response was developed. This model is based on the observation of DNA damage in shielded parts of rat lung that was assumed relevant to cell lethality and consequently overall lung response. RESULTS: While the experimental data indicated directional or regional volume effects, the applicability of dose and volume as sole predictors of lung response to radiation was found to be unreliable for lower lung (base) irradiation in mice. This conforms well to rat lung response where micronuclei were observed in shielded apical parts of lung following base irradiation. The radiobiological model, which was specifically developed to account for the lung response outside of primary irradiated volume, provides a good fit to mice lethality data, using parameters inferred from rat micronuclei data. CONCLUSION: Response to lung irradiation in rodents, in particular, elevated sensitivity to base irradiation, can be interpreted with a hypothesis of in-field and out-of-field effects for cellular response. If the existence of these effects for lung is subsequently proven in humans, it will require the incorporation of geometrical and directional information in normal tissue complication probability calculations for lung. These considerations are ignored in present approaches based only on conventional dose-volume histograms.

Decreased pulmonary radiation resistance of manganese superoxide dismutase (MnSOD)-deficient mice is corrected by human manganese superoxide dismutase-Plasmid/Liposome (SOD2-PL) intratracheal gene therapy.

The pulmonary ionizing radiation sensitivity of C57BL/6 Sod2(+/-) mice heterozygous for MnSOD deficiency was compared to that Sod2(+/+) control littermates. Embryo fibroblast cell lines from Sod2(-/-) (neonatal lethal) or Sod2(+/-) mice produced less biochemically active MnSOD and demonstrated a significantly greater in vitro radiosensitivity. No G(2)/M-phase cell cycle arrest after 5 Gy was observed in Sod2(-/-) cells compared to the Sod2(+/-) or Sod2(+/+) lines. Subclonal Sod2(-/-) or Sod2(+/-) embryo fibroblast lines expressing the human SOD2 transgene showed increased biochemical activity of MnSOD and radioresistance. Sod2(+/-) mice receiving 18 Gy whole-lung irradiation died sooner and had an increased percentage of lung with organizing alveolitis between 100 and 160 days compared to Sod2(+/+) wild-type littermates. Both Sod2(+/-) and Sod2(+/+) littermates injected intratracheally with human manganese superoxide dismutase-plasmid/liposome (SOD2-PL) complex 24 h prior to whole-lung irradiation showed decreased DNA strand breaks and improved survival with decreased organizing alveolitis. Thus underexpression of MnSOD in the lungs of heterozygous Sod2(+/-) knockout mice is associated with increased pulmonary radiation sensitivity and parallels increased radiation sensitivity of embryo fibroblast cell lines in vitro. The restoration of cellular radioresistance in vitro and in lungs in vivo by SOD2-PL transgene expression supports a potential role for SOD2-PL gene therapy in organ-specific radioprotection.

Manganese [correction of Magnesium] superoxide dismutase (MnSOD) plasmid/liposome pulmonary radioprotective gene therapy: modulation of irradiation-induced mRNA for IL-I, TNF-alpha, and TGF-beta correlates with delay of organizing alveolitis/fibrosis.

Radiation pneumonitis remains a critical dose-limiting toxicity of total body irradiation (TBI) for use in bone marrow transplantation. The acute and chronic phases of radiation damage in the mouse lung have been shown to correlate with mouse strain genotype and are dependent on fraction size, total dose, and total lung volume. Our prior studies demonstrated effective prevention of irradiation-induced lung damage and improved survival in C57BL/6J mice by MnSOD plasmid/liposome gene therapy. In the present studies, we investigated the kinetics of irradiation-induced upregulation of mRNA for acute phase cytokines interleukin (IL)-1 and tumor necrosis factor (TNF)-alpha, and fibrosis-associated transforming growth factor (TGF)-beta and isoforms (TGF-beta1, TGF-beta2 and TGF-beta3) in 2000 cGy whole-lung irradiated C57BL/6J mice, a strain known to develop dose and volume-dependent organizing alveolitis/fibrosis. The results demonstrate increase in mRNA for IL-1 between days 1 and 14 after irradiation with return to baseline levels out to 120 days. TNF-alpha mRNA levels were not initially elevated but increased between 80 and 100 days and then decreased by 120 days. The mRNA levels for TGF-beta1 demonstrated an initial increase within the first 14 days after total lung irradiation with a decrease to baseline levels out to 100 days. Then, in striking contrast to the other two cytokines, an increase in TGF-beta2 mRNA occurred at around 120 days and correlated with the detection of organizing alveolitis/radiation fibrosis and mortality. These results are consistent with a two-phase mechanism in the molecular pathology of irradiation lung injury, in which IL-1 cytokine mRNA levels correlated with the acute pneumonitis phase and delayed elevation of TNF-alpha (80-100 days), TGF-beta1 (100 days), and TGF-beta2 (120 days) were associated with the fibrosis phase. Insight into the cell-specific and tissue-specific molecular mechanisms of ionizing irradiation induction of mRNA for pulmonary cytokines may provide new strategies for treatment of radiation pneumonitis in TBI patients.

Intratracheal injection of adenovirus containing the human MnSOD transgene protects athymic nude mice from irradiation-induced organizing alveolitis.

PURPOSE: A dose and volume limiting factor in radiation treatment of thoracic cancer is the development of fibrosis in normal lung. The goal of the present study was to determine whether expression prior to irradiation of a transgene for human manganese superoxide dismutase (MnSOD) or human copper/zinc superoxide dismutase (Cu/ZnSOD) protects against irradiation-induced lung damage in mice. METHODS AND MATERIALS: Athymic Nude (Nu/J) mice were intratracheally injected with 10(9) plaque-forming units (PFU) of a replication-incompetent mutant adenovirus construct containing the gene for either human MnSOD, human copper/zinc superoxide dismutase (Cu/ZnSOD) or LacZ. Four days later the mice were irradiated to the pulmonary cavity to doses of 850, 900, or 950 cGy. To demonstrate adenoviral infection, nested reverse transcriptase-polymerase chain reaction (RT-PCR) was carried out with primers specific for either human MnSOD or Cu/ZnSOD transgene on freshly explanted lung, trachea, or alveolar type II cells, and immunohistochemistry was used to measure LacZ expression. RNA was extracted on day 0, 1, 4, or 7 after 850 cGy of irradiation from lungs of mice that had previously received adenovirus or had no treatment. Slot blot analysis was performed to quantitate RNA expression for IL-1, tumor necrosis factor (TNF)-alpha, TGF-beta, MnSOD, or Cu/ZnSOD. Lung tissue was explanted and tested for biochemical activity of MnSOD or Cu/ZnSOD after adenovirus injection. Other mice were sacrificed 132 days after irradiation, lungs excised, frozen in OCT, (polyvinyl alcohol, polyethylene glycol mixture) sectioned, H&E stained, and evaluated for percent of the lung demonstrating organizing alveolitis. RESULTS: Mice injected intratracheally with adenovirus containing the gene for human MnSOD had significantly reduced chronic lung irradiation damage following 950 cGy, compared to control mice or mice injected with adenovirus containing the gene for human Cu/ZnSOD or LacZ. Immunohistochemistry for LacZ protein in adenovirus LacZ (Ad-LacZ)-injected mice demonstrated expression of LacZ in both the upper and lower airway. Nested RT-PCR showed lung expression of MnSOD and Cu/ZnSOD for at least 11 days following infection with each respective adenovirus construct. Nested RT-PCR using primers specific for human MnSOD demonstrated increased expression of the human MnSOD transgene in the trachea and alveolar type II cells 4 days after virus injection on the day of irradiation. At this time point, increased biochemical activity of MnSOD and Cu/ZnSOD respectively, was detected in lungs from these two adenovirus groups, compared to each other or to control or adenovirus LacZ mice. Slot blot analysis of RNA from lungs of mice in each group following 850 cGy irradiation demonstrated decreased expression of mRNA for interleukin-I (IL-1), TNF-alpha, and transforming growth factor-beta (TGF-beta) in the MnSOD adenovirus-injected mice, compared to irradiated control, LacZ, or Cu/ZnSOD adenovirus-injected, irradiated mice. Mice receiving adenovirus MnSOD showed decreased organizing alveolitis at 132 days in all three dose groups, compared to irradiated control or Ad-LacZ, or Ad-Cu/ZnSOD mice. CONCLUSIONS: Overexpression of MnSOD in the lungs of mice prior to irradiation prevents irradiation-induced acute and chronic damage quantitated as decreased levels of mRNA for IL-1, TNF-alpha, and TGF-beta in the days immediately following irradiation, and decrease in the percent of lung demonstrating fibrosis or organizing alveolitis at 132 days. These data provide a rational basis for development of gene therapy as a method of protection of the normal lung from acute and chronic sequelae of ionizing irradiation.

Changes in histology and fibrogenic cytokines in irradiated colorectum of two murine strains.

PURPOSE: A strain difference in the development of radiation-induced fibrosis of the colorectum was recently observed. C57B1/6 mice developed colorectal obstruction with significantly higher incidence compared to C3Hf/Kam mice after partial volume irradiation with 30 Gy. Previous reports have demonstrated differences in cytokine mRNA levels in fibrosis-prone and -resistant mice after lung irradiation. The aims of this study are to determine if there are strain differences in: 1) the histology of the lesion, 2) mRNA levels for transforming growth factor beta (TGFbeta) isoforms and tumor necrosis factor alpha (TNFalpha), and 3) immunohistochemical staining patterns using antibodies against the TGFbeta isoforms and latency-associated peptide (LAP). METHODS AND MATERIALS: The colorectum of male C3Hf/Kam (C3H) and C57B1/6 (B6) mice were irradiated using a dose/length combination (30 Gy to 13.7 mm) that resulted in 10 or 100% incidence of obstruction by 6 months in each strain, respectively. Colorectal tissue was removed from 6 hours to 120 days after irradiation as well as from obstructed mice and prepared for histology, RNase protection assay, and immunofluorescence. RESULTS: Distinct differences in the histological phenotype for the two strains were observed at times preceding obstruction. Samples from B6 mice showed increased hyperplastic crypts, colitis cystica profunda, and fibrosis within the lamina propria, compared to identically treated C3H mice. Fibrosis in the lamina propria of B6 mice appeared early, beginning at 75 days after irradiation, and was progressive, whereas fibrosis in C3H mice appeared simultaneous with obstruction and may have been a reaction to ulceration. No consistent strain difference in mRNA levels for TGFbeta1, 2, 3 or TNFalpha were observed, although mRNA levels of TGFbeta1 and TNFalpha were significantly elevated in both strains relative to nonirradiated controls. Immunofluorescent staining for TGFbeta1, 3 and LAP was observed in hyperplastic crypts and colitis cystica profunda adjacent to regions of fibrosis, histological changes that were present predominately in the B6 strain. CONCLUSIONS: The response of the colorectum to irradiation involves changes in the expression of several different cytokines. However, the lack of a consistent strain difference in TGFbeta1, 2, 3 and TNFalpha mRNA levels, despite strain differences in both the incidence of colorectal obstruction and histological features preceding obstruction, suggests that mRNA changes in these fibrogenic cytokines are not the critical determinant of the strain difference and are not related to the process of radiation-induced colorectal fibrosis in these mouse strains. Strain-dependent differences were observed in the localization of active TGFbeta, but these differences were related to the histological changes specifically found in the irradiated colon of the B6 strain.

Murine strain differences in the volume effect and incidence of radiation-induced colorectal obstruction.

PURPOSE: Interindividual variation in the level of normal tissue damage after radiotherapy has been clinically observed. Murine models have suggested that there may be a genetic component to the variation in susceptibility of different radiation-induced normal tissue complications. Currently, there are no experimental data available describing interstrain differences in the "volume effect" for irradiated normal tissues, such as the colorectum. The aims of this study are to determine if there are strain differences in: 1. the incidence of colorectal obstruction; and 2. the volume effect, after irradiation of the colorectum using two mouse strains that are known to vary in their susceptibility for developing pulmonary fibrosis. METHODS AND MATERIALS: Various lengths (5.2 to 22.9 mm) of the colorectum of male C57B1/6 and C3Hf/Kam mice were irradiated with a single dose (30 Gy) of 137Cs gamma rays. Also, various doses (20 to 35 Gy) were given to a single length (22.9 mm) of colorectum. The incidence of obstruction was determined as a function of length and dose at 6 months after irradiation. The Threshold Probability model was fit to the length-response data. RESULTS: C57B1/6 mice developed colorectal obstruction at significantly higher incidence than C3Hf/Kam mice at all lengths after a single dose of 30 Gy. In addition, the data showed a strain difference in the threshold length of colorectum that had to be irradiated before obstructions were observed. CONCLUSION: Strain differences in the incidence of radiation-induced colorectal obstruction were observed, consistent with previous studies that showed a strain difference in radiation-induced pulmonary fibrosis. The presence of a threshold length of colorectum that was different for the two strains is consistent with the concept that there may be a critical threshold amount of colorectal tissue that can tolerate a high dose without complication, and that the dimensions of the threshold may vary among individuals.

Factors influencing the development of lung fibrosis after chemoradiation for small cell carcinoma of the lung: evidence for inherent interindividual variation.

PURPOSE: Clinical observations often reveal individual differences in the severity of lung fibrosis after definitive radiation therapy for lung cancer. Recent experimental studies suggest that the risk of developing lung fibrosis may be genetically controlled. The present study was undertaken to examine the magnitude of individual variation in the incidence and severity of lung fibrosis in a well-defined patient population treated by concurrent chemoradiation for limited small-cell lung carcinomas (LSCLC). MATERIALS AND METHODS: Between 1989 and 1994, 56 patients with LSCLC were enrolled in one of two controlled prospective studies of concurrent chemotherapy and concomitant conventional (45 Gy in 25 fractions q.d. over 5 weeks) or accelerated (45 Gy in 30 fractions b.i.d. over 3 weeks) radiotherapy. Chemotherapy consisted of cisplatin and etoposide (PE) or PE plus ifosfamide and mesna (PIE). Of the 56, a group of 25 patients who had serial computerized tomography (CT) examinations of the chest and were deemed to have unequivocal radiographic complete responses were selected for this study. The severity of lung fibrosis was recorded for each patient from the CT images using an arbitrary scale (0 to 3) at 1 year after treatment. Radiographic fibrosis scores were recorded on 1-3 CT slices in 3 different dose-areas (20-30 Gy; 30-40 Gy; and >40 Gy) that were defined using the corresponding CT slices from the patient's CT treatment plan. Of these patients, 23 (92%) had at least 2 slices scored; 11 patients had all 3 slices scored. RESULTS: Among the clinical and treatment parameters investigated (including type of chemotherapy), only total dose and fractionation schedule were identified as significant and independent determinants of lung fibrosis. Radiographic fibrosis scores were higher in high-dose areas and among patients treated with the accelerated schedule. Using a fit of the proportional odds (PO) model based on the total dose and fractionation schedule, fibrosis score residuals were calculated for each patient. The residual for each score is defined as the difference between the observed and expected score based on the dose and treatment schedule received. Average residuals varied significantly among patients (p = 0.005, Kruskal-Willis test). Using a modified version of the PO model, the coefficient of variation in patient heterogeneity was estimated to be 10.1% (95% confidence interval: 6.2-14.9%). Inclusion of the heterogeneity factor, in addition to total dose and fractionation schedule, improved the fit of the PO model to an extremely high level of significance (p < 10(-7)). CONCLUSIONS: Our data indicate that the risk and severity of lung fibrosis analyzed radiographically on CT images increases with total dose and with the use of an accelerated radiation schedule, for patients treated with chemoradiation for small-cell lung cancer. There was also demonstrable patient-to-patient heterogeneity, suggesting that the risk of lung fibrosis is strongly affected by inherent factors that vary among individuals.

Volume effects and epithelial regeneration in irradiated mouse colorectum.

The use of three-dimensional treatment planning and volume-reduction techniques in radiotherapy has prompted the development of a number of mathematical models to describe the effect of changing treatment volume on the probability of associated complications in normal tissues. However, limited data are available to test or support these models. One prediction of the Probability model and analogous models, which describe the volume-effect relationship for late end points in tissues with a series-type arrangement of functional subunits, is that there is no threshold volume in the development of the end point. This hypothesis was tested in mouse colorectum, a normal tissue with functional subunits suggested to be arranged in series, using the incidence of obstructions due to consequential fibrosis as the end point of damage. Various lengths of the colorectum of C3Hf/Kam mice were irradiated with single doses of 250 kVp X rays. A threshold length between 10 and 15 mm was observed after 32 Gy. The Probability model could not describe the data adequately, but a modified version that included a threshold volume term (the Threshold Probability model) provided an excellent fit. In a separate experiment, epithelial regeneration (migration, extracryptal proliferation and formation of new crypts) was examined as a possible mechanism for the threshold length. Re-epithelialization was complete after 32 Gy was delivered to lengths below (5 or 10 mm) but not above (20 mm) the threshold for consequential obstruction. Proliferation of epithelial cells outside the crypt on the mucosal surface (i.e. extracryptal proliferation) may contribute to the regeneration process. The data indicate that regeneration of the epithelium after irradiation results in a threshold length of the colorectum in the development of consequential fibrosis, in contradiction to predictions of the Probability model.

Murine susceptibility to radiation-induced pulmonary fibrosis is influenced by a genetic factor implicated in susceptibility to bleomycin-induced pulmonary fibrosis.

From evidence of interpatient variability in normal tissue sensitivity to radiotherapy and from radiation studies using inbred mouse strains, it is hypothesized that individual variation in susceptibility to radiation-induced pulmonary fibrosis is genetically controlled. A genetic model has been developed from the fibrosis-prone C57BL/6J and the fibrosis-resistant C3Hf/Kam mouse strains. Inheritance of the fibrotic phenotype was characterized in F1 and F2 (F1 intercross) generations derived from the parental strains. Genetic mapping was used to determine whether the quantitative trait loci (QTL), which influence susceptibility to bleomycin-induced lung fibrosis in these progenitor strains, could be implicated in susceptibility to radiation-induced lung fibrosis. Mice were treated with 14 or 16 Gy (60Co) to the whole thorax. The doses were selected to investigate the response at the LD50 and LD100 of C3Hf/Kam mice. The animals were sacrificed 33 weeks after treatment or when moribund. The percentage of lung with fibrosis for each mouse was quantified with image analysis of a histological section of the lung. For both the 14- and 16-Gy data sets, heritability was estimated at 38 +/- 11%, and the number of genetic factors influencing susceptibility to pulmonary fibrosis was estimated to be one or two. Two hundred fifty-five F2 intercross mice were genotyped with markers at the bleomycin loci on chromosomes 11 and 17 (chromosome 17 marker is at the major histocompatibility complex). Genetic linkage was established for the marker on chromosome 17 (P = 3.0 x 10(-6)), which accounts for 6.6% of the F2 phenotypic variance but not for the markers surrounding the QTL on chromosome 11 (P = 0.37). The inheritance data suggested that susceptibility to radiation-induced pulmonary fibrosis is a heritable trait controlled by two genetic loci, and through genomic mapping, a QTL on chromosome 17 was identified as one of the loci.

Spatial heterogeneity of the volume effect for radiation pneumonitis in mouse lung.

PURPOSE: In a previous study to determine the effect of partial volume irradiation on damage and morbidity from pneumonitis in mouse lung, a critical determinant of the volume effect was the spatial location of the irradiated subvolume within the lung. The goals of the present study were to (a) define the dose-volume effect curves for radiation pneumonitis in mouse lung, (b) define the threshold volume, and (c) further investigate the spatial heterogeneity of the radiosensitivity of mouse lung. METHODS AND MATERIALS: Eight fractional volumes ranging from 94% to 17% of the lungs of C3Hf/Kam mice were irradiated with single doses ranging from 12 to 22 Gy, depending on the volume irradiated. The fractional volumes irradiated were determined from computed tomographic scans of mouse lung. To determine the effect of location of irradiated subvolume, equivalent volumes in the base and the apex were irradiated by shielding the prescribed adjacent volume in the apex or base respectively. Dose-response curves of breathing rate at 22 weeks and lethality at 28 weeks were constructed for each subvolume irradiated in the apex or base and fitted by logit analysis, and ED50s and LD50s with 95% confidence limits obtained, respectively. Lungs from dead mice or mice sacrificed when moribund were examined for histologic signs of pneumonitis. RESULTS: Irradiation of any of the eight subvolumes in the base yielded a consistently lower isoeffect dose for both assays of radiation pneumonitis than if the same irradiated subvolume was located in the apex. Plots of isoeffect dose for breathing rate as a function of subvolume irradiated in the base or apex showed that these curves were not linear but exhibited a plateau between irradiated volumes of 70% and 80% in both the apex and base. A similar curve was obtained for lethality and volume irradiated in the base. A threshold volume, i.e., irradiation of that volume that should produce no changes in breathing rate or mortality, was dependent on the location of the irradiated subvolume. CONCLUSION: The response of mouse lung to partial volume irradiation is heterogeneous and is critically dependent on the specific location of the irradiated subvolume in the lung, i.e., a given subvolume in the base is consistently more sensitive than the same subvolume in the apex using either breathing rate or lethality as assays of radiation pneumonitis. We suggest that this heterogeneity is due to the anatomy of the tracheobronchial tree, i.e., to the distribution of non-gas exchange-conducting airways in the irradiated volume. These data have implications for the modeling of dose-volume effects in the lung and the prediction of normal tissue complication probabilities for radiation pneumonitis in humans.

Estimation of the spatial distribution of target cells for radiation pneumonitis in mouse lung.

PURPOSE: Recent studies of Liao et al. and Travis et al. have demonstrated that irradiation of cross-sectional partial volumes contiguous to the base of mouse lung produces a higher incidence of pneumonitis than irradiation of equally sized subvolumes contiguous to the apex. One interpretation of this finding is that the critical target cells for pneumonitis are not distributed uniformly throughout the lung. The purpose of the present study was to test this interpretation by obtaining an estimate of the spatial distribution of the critical target cells for pneumonitis in mouse lung, based on the partial-volume data. METHODS AND MATERIALS: A mathematical model was derived describing the probability of radiation pneumonitis as a function of dose, volume of lung irradiated, and location in the lung of the irradiated subvolume. The model includes a nonparametric description of the spatial target-cell distribution in lung, to be estimated from data. The model was fitted to the lethality data of Liao et al. and Travis et al. to obtain estimates of the proportion of target cells contained in each of various subvolumes of the lung. RESULTS: The results indicate that the critical target cells in mouse lung are concentrated in the base and, to a somewhat lesser extent, in the apex of the lung, with fewer cells in the middle region. The estimated spatial distribution of target cells in mouse lung agrees well with the distribution of alveoli, whose concentration in the midlung is limited by the presence of the major conducting airways. CONCLUSION: Heterogeneity in the spatial distribution of critical target cells in normal tissue implies that the complication probability (NTCP) depends on the location in the organ of the irradiated subvolume, as well as on radiation dose and subvolume size. Calculations using an NTCP model for mouse lung indicate that irradiation of equal subvolumes of lung with the same dose can lead to complication probabilities covering the full range from 0 to 100%, depending only on the location in the lung of the irradiated subvolume.

Potentiation of murine MCa-4 carcinoma radioresponse by 9-amino-20(S)-camptothecin.

9-Amino-20(S)-camptothecin (9-AC) has demonstrated efficacy against several human cancer xenografts, including cancers of the colon, breast, lung, ovary, and stomach and malignant melanoma, and is currently undergoing Phase I clinical trials. In vitro data indicate that the addition of topoisomerase I inhibitors shortly after irradiation causes conversion of single-strand breaks to double-strand breaks, resulting in synergistic lethality to cultured log-phase or quiescent malignant cells. In our study, the efficacy of 9-AC as a potential radiosensitizing agent in vivo was assessed in C3Hf/Kam female mice bearing 7.6-8-mm MCa-4 mammary tumors implanted i.m. into the right posterior thigh. In one series of experiments to determine the dose dependence of 9-AC, mice were injected twice a week with either 0.5, 1.0, or 2.0 mg/kg 9-AC (total doses of 2, 4, and 8 mg/kg, respectively) either alone or 1 h before irradiation. In a second series of experiments, the schedule dependence of 9-AC was determined by giving a constant total dose of 4 mg/kg 9-AC once (2 mg/kg), twice (1 mg/kg every third day), or four (0.5 mg/kg every other day) times per week for 2 weeks, either alone or combined with radiation. The same radiation regimen was used in all experiments: 2-Gy fractions daily for 14 consecutive days, giving a total dose of 28 Gy to the tumor-bearing leg only. Tumor response was assessed by regrowth delay and dose modification factors (DMFs) obtained by comparing regrowth delay in the groups given 9-AC alone with those given the same dose of 9-AC and radiation. 9-AC significantly delayed tumor growth when combined with radiation, and this effect was dependent on drug dose; DMFs of 2.4 [95% confidence interval (CI), 2.0-3.1], 3.7 (95% CI, 3.1-4.6), and 3.3 (95% CI, 2.7-4.1) were obtained for groups treated with total drug doses of 2.0, 4.0, and 8.0 mg/kg 9-AC, respectively. In addition, the same total dose of 4 mg/kg 9-AC was more effective when given either twice or four times a week compared with once a week, giving DMFs of 2.8 (95% CI, 2.2-3.9), 2.6 (95% CI, 2.0-3.6), and 1.7 (95% CI, 1.3-2.4), respectively. The effect of 9-AC and radiation on normal tissue toxicity was assessed in two normal tissues, jejunum and skin, in separate groups of mice. Jejunal crypt cell survival was decreased in those mice given single doses of 9-AC ranging from 0.5-4.0 mg/kg and 12.5 Gy of total body radiation compared with those given 12.5 Gy of total body irradiation alone. The same regimen of drug and radiation did not modify acute skin reactions. These results suggest that 9-AC is an effective in vivo radiosensitizing agent when given in divided doses with fractionated irradiation. In addition, the gastrointestinal tract but not skin could be a critical target tissue for the use of 9-AC combined with radiation.

Fibroblast radiosensitivity in vitro and lung fibrosis in vivo: comparison between a fibrosis-prone and fibrosis-resistant mouse strain.

Radiation-induced pneumonitis and fibrosis in the lung after treatment to the thoracic cavity for malignant disease currently limit the maximum tolerated dose to that region. It has been suggested that heterogeneity in susceptibility to radiation-induced fibrosis exists in the population, implying that the lung tolerance dose is defined by a sensitive subset of the patient population. Studies of radiotherapy patients have indicated that the survival at 2 Gy (SF2) of cultured skin fibroblasts correlates with the incidence and severity of postirradiation damage in a number of tissues, suggesting that this assay may be a useful predictor of late tissue effects. The goal of the studies presented here was to determine if the radiosensitivity of fibroblasts in vitro isolated from mouse lungs was correlated with the severity of radiation-induced fibrosis in the lungs of two inbred strains of mice previously shown to differ markedly in their susceptibility to radiation-induced lung fibrosis: the C3Hf/Kam strain, classified as fibrosis-resistant, and the C57BL/6J strain, classified as fibrosis-prone. Quantitative measurements of lung fibrosis after irradiation were compared to SF2 values for fibroblasts of skin and lung cultured from each strain. Lung fibrosis was quantified, using computerized image analysis, as the percentage of fibrosis on Masson's Trichrome-stained lung sections from both strains after single doses of radiation to the thorax. For the measurements of SF2, fibroblasts plated at the second passage and grown to confluence were given single doses of radiation ranging from 0 to 6 Gy. Survival curves were constructed and SF2 values obtained from a linear-quadratic fit to the data. The radiosensitivity of fibroblasts from the lung and skin of SCID mice was determined and served as a positive control. The percentage of radiation-induced lung fibrosis was significantly different between the two strains, 5.1% and 0.2% in the C57 strain and C3H strain, respectively. Follow-up of long-term survivors (two mice) from the C3H strain did not change this conclusion. However, the lung fibroblast SF2 for the C57BL/6J strain (fibrosis-prone), 0.50 +/- 0.03, was not statistically different from the C3Hf/Kam strain (fibrosis-resistant), 0.55 +/- 0.07. These data indicate that in vitro radiosensitivity of lung fibroblasts as assayed by survival at 2 Gy does not correlate with the development of lung fibrosis in this mouse model. The SF2 for lung fibroblasts from SCID mice was 0.10. Similar SF2 values were obtained for both the C3Hf/Kam mouse lung and skin fibroblasts, 0.55 and 0.56, respectively, and C57BL/6J mouse lung and skin fibroblasts, 0.50 and 0.52, respectively, indicating that the radiosensitivity of fibroblasts isolated from lung and skin within a strain is the same.

Inheritance of susceptibility to bleomycin-induced pulmonary fibrosis in the mouse.

Based on the range of patient responses to treatment, and on animal studies, it is hypothesized that individual variation in sensitivity to bleomycin-induced pulmonary fibrosis is controlled genetically. A genetic model has been developed by (a) establishing a distinct difference in bleomycin-induced lung damage in two inbred strains of mice [parental generation: C57BL/6J (fibrosis-prone phenotype) and C3Hf/Kam (fibrosis-resistant phenotype)] and (b) characterizing inheritance of the fibrosing phenotype in the F1 (first filial) and F2 (F1 intercross; second filial) generations derived from the parental strains. Male mice received 100 mg/kg and female mice 125 mg/kg of bleomycin via s.c. osmotic minipump. The animals were sacrificed 8 weeks after treatment or when their breathing rate indicated respiratory distress. The percentage of lung with fibrosis for each mouse was quantified with image analysis of a histological section of the left lung. The mean percentage of fibrosis for the C57BL/6J males was 8.4 +/- 0.8% (SE) and 4.4 +/- 0.8% for females, and the C3Hf/Kam mice of either sex did not present the fibrosing lesion (mean score, 0%). Significant difference (P = 6 x 10(-6)) was measured in percentage of fibrosis between the two strains of F1 males, but not F1 females (P = 0.38), suggesting the presence of an X-linked factor associated with the fibrosing phenotype. From an ANOVA the X-linked factor is estimated to contribute 19% of the fibrosis phenotype. A genetic model of two or three loci controlling the fibrosing phenotype is proposed from the data of the parental, F1, and F2 generations. The mouse model demonstrates that susceptibility to bleomycin-induced pulmonary fibrosis is a heritable trait controlled by a few genetic loci.

The use of radiochromic film to measure dose distributions resulting from high dose rate 192Iridium single catheter treatments.

PURPOSE: Radiochromic film was used to measure and compare the dose distributions parallel to a high dose rate (HDR) 192Iridium (192Ir) brachytherapy afterloading catheter that resulted from optimized treatment plans using various combinations of prescribed dose magnitude and location as well as source spacing. METHODS AND MATERIALS: Differences exist among clinical investigators for specification of the magnitude and location of prescribed treatment dose for brachytherapy irradiations using HDR 192Ir afterloading. Typical prescriptions for endobronchial irradiation include 5 to 10 Gy at 10 mm or 15 Gy at 6 mm measured from the center of the afterloading catheter. The dose distributions that result from these irradiations are very difficult to quantify by conventional dosimetry methods. This study used radiochromic film to measure the dose distributions resulting from optimized treatment plans for source dwell position separations of 2.5 or 5.0 mm and for a prescribed treatment dose of either 15 Gy at 6 mm or 5 Gy at 10 mm, conditions that have been used at M. D. Anderson Cancer Center for the treatment of endobronchial lesions. An acrylic phantom was designed to allow for measurement of the dose distributions at 0.95 mm (catheter surface), 6 mm, and 10 mm from and parallel to the catheter for sources positioned along either 20 or 80 mm of the catheter. RESULTS: Radiochromic film is shown to be a suitable quality assurance and dosimetry modality for the measurement of the dose distribution along an afterloading catheter resulting from an HDR I92Ir source. Each of the treatment plans was about equally effective in being able to produce a uniform dose distribution at their respective planned target distances. Differences were more apparent when comparing the dose distributions at nontargeted distances. On the catheter surface the dose was very nonuniform and in the case of 2.5 mm source spacing along 20 mm of catheter with target dose planned to 10 mm, the central minimum dose was only 13 to 24% of the dose opposite to the most proximal and distal sources. The absolute doses measured at equivalent distances for the 15 Gy planned to 6 mm treatments are about 1.3 to 1.5 times higher than those measured for the 5 Gy planned to 10 mm treatments. It was also observed that the lateral positioning of the encapsulated source within the afterloading catheter can contribute to dose differences about the catheter that are greatest for measurements made in contact with the catheter surface (24 to 40%) but may also be large at the treatment planning distances of 6 (0 to 15%) and 10 mm (0 to 9%). CONCLUSION: At their respective treatment planning distances of 6 or 10 mm, each of the treatment plans produced dose distributions of comparable uniformity. Against the catheter, relatively more uniform dose distributions with higher minimum doses were obtained for (a) dose prescription at 6 mm, rather than at 10 mm; (b) source separation of 2.5 mm, rather than 5.0 mm (except for a 20 mm active catheter length with dose planned to 10 mm); and (c) longer active length of the catheter of 80 mm, rather than 20 mm.