Impact of Inter-Individual Variance in the Expression of a Radiation-Responsive Gene Panel Used for Triage.

In previous studies we determined a gene expression signature in baboons for predicting the severity of hematological acute radiation syndrome. We subsequently validated a set of eight of these genes in leukemia patients undergoing total-body irradiation. In the current study, we addressed the effect of intra-individual variability on the basal level of expression of those eight radiation-responsive genes identified previously, by examining baseline levels in 200 unexposed healthy human donors (122 males and 88 females with an average age of 46 years) using real-time PCR. In addition to the eight candidate genes ( DAGLA, WNT3, CD177, PLA2G16, WLS, POU2AF1, STAT4 and PRF1), we examined two more genes ( FDXR and DDB2) widely used in ex vivo whole blood experiments. Although significant sex- (seven genes) and age-dependent (two genes) differences in expression were found, the fold changes ranged only between 1.1-1.6. These were well within the twofold differences in gene expression generally considered to represent control values. Age and sex contributed less than 20-30% to the complete inter-individual variance, which is calculated as the fold change between the lowest (reference) and the highest Ct value minimum-maximum fold change (min-max FC). Min-max FCs ranging between 10-17 were observed for most genes; however, for three genes, min-max FCs of complete inter-individual variance were found to be 37.1 ( WNT3), 51.4 ( WLS) and 1,627.8 ( CD177). In addition, to determine whether discrimination between healthy and diseased baboons might be altered by replacing the published gene expression data of the 18 healthy baboons with that of the 200 healthy humans, we employed logistic regression analysis and calculated the area under the receiver operating characteristic (ROC) curve. The additional inter-individual variance of the human data set had either no impact or marginal impact on the ROC area, since up to 32-fold change gene expression differences between healthy and diseased baboons were observed.

The effects of knockdown of wild-type survivin, survivin-2B or survivin-delta3 on the radiosensitization in a soft tissue sarcoma cells in vitro under different oxygen conditions.

The inhibitor of apoptosis wild-type survivin is a multifunctional protein that suppresses apoptosis and regulates cell cycle progression. An association between wild-type survivin expression and radiosensitivity has been described in different tumor cells. The effects of siRNA-induced knockdown of wild-type survivin and survivin-splice variants survivin-2B and survivin-Delta3 were investigated under normoxic and hypoxic conditions in the human sarcoma cell line US 8-93 (mutant p53). Inhibition of the survivin isoforms by siRNA resulted in a decrease of target mRNA down to 14-70% compared to cells treated with control siRNA independent of the oxygen level. The mRNA expression of survivin isoforms was decreased by the factor of 1-12 when the cells were cultivated under hypoxic conditions. Moreover, the knockdown of wild-type survivin reduced colony formation independent of oxygen concentration down to 70% and induced formation of polyploid cells. Less reduction of plating efficiency was observed after specific knockdown of survivin-2B and survivin-Delta3 under hypoxic or normoxic conditions. A knockdown of wild-type survivin, survivin-Delta3 and survivin-2B isoforms in combination with irradiation caused no radiosensitization in cell line US 8-93, neither under hypoxic nor under normoxic conditions tested in the colony-forming assay. However, knockdown of wild-type survivin caused radiosensitization in the megacolony assay.

Gamma ray-induced bystander effect in tumour glioblastoma cells: a specific study on cell survival, cytokine release and cytokine receptors.

Recent experimental evidence has challenged the paradigm according to which radiation traversal through the nucleus of a cell is a prerequisite for producing genetic changes or biological responses. Thus, unexposed cells in the vicinity of directly irradiated cells or recipient cells of medium from irradiated cultures can also be affected. The aim of the present study was to evaluate, by means of the medium transfer technique, whether interleukin-8 and its receptor (CXCR1) may play a role in the bystander effect after gamma irradiation of T98G cells in vitro. In fact the cell specificity in inducing the bystander effect and in receiving the secreted signals that has been described suggests that not only the ability to release the cytokines but also the receptor profiles are likely to modulate the cell responses and the final outcome. The dose and time dependence of the cytokine release into the medium, quantified using an enzyme linked immunosorbent assay, showed that radiation causes alteration in the release of interleukin-8 from exposed cells in a dose-independent but time-dependent manner. The relative receptor expression was also affected in exposed and bystander cells.

The effects of low-dose X-irradiation on the oxidative burst in stimulated macrophages.

PURPOSE: Local irradiation with a dose of around 0.5 Gy is an effective treatment of acute necrotizing inflammations. The hypothesis that low doses of X-rays modulate the oxidative burst in activated macrophages, which plays a major role in the acute inflammatory process, was tested. MATERIALS AND METHODS: Murine RAW 264.7 macrophages were stimulated with LPS/gammaIFN, PMA or zymosan and oxidative burst was measured using either DCFH-DA or by reduction of cytochrome-C. Radiation doses of 0.3-10 Gy were given shortly before or after stimulation. RESULTS: Low X-ray doses of <1 Gy significantly reduced the oxidative burst in activated macrophages, whereas higher doses had little effect on oxidative burst. CONCLUSIONS: The modulation of oxidative burst by low radiation doses may contribute to the therapeutic effectiveness of low-dose radiotherapy of acute necrotizing inflammations.

Mononuclear cell adhesion and cell adhesion molecule liberation after X-irradiation of activated endothelial cells in vitro.

PURPOSE: Increased expression of cell adhesion molecules on endothelial cells is an important early event in inflammation. Low-dose radiotherapy is very effective anti-inflammatory treatment. The hypothesis that it may act by modulation of cell adhesion molecule expression in activated endothelial cells and the subsequent adhesion of mononuclear cells onto the activated endothelial cells was tested. MATERIALS AND METHODS: EA.hy.926 endothelial cells were irradiated with 0.3-10 Gy X-rays at different times before or after stimulation with TNFalpha. ICAM-1 or E-selectin expression was measured by ELISA and FACS. Isolated peripheral blood mononuclear cells were incubated with an activated and irradiated confluent monolayer of endothelial cells 4 h, 12 h or 24 h after stimulation, and adhesion was determined in dynamic and static adhesion assays. RESULTS: In the static adhesion assay, where integrin-mediated adhesion dominates, radiation doses of 0.3-0.6 Gy reduced the adhesion of mononuclear cells onto EA.hy.926-EC in vitro by 25-40% and 15-25% of the control level 4 h and 24 h after stimulation, respectively, but increased adhesion 12 h after stimulation. In the dynamic adhesion assay, where selectin-mediated adhesion dominates, radiation doses of 0.3-0.6 Gy reduced the adhesion events by 40-50% and 30-40% of the control level 4 h and 24 h after stimulation, respectively, and again increased adhesion 12h after stimulation. X-ray doses of < or =5 Gy did not induce ICAM-1 expression, or modulate TNFalpha-induced ICAM-1 expression. E-selectin expression was, however, increased in a dose-dependent way 6 h after irradiation. In contrast, X-irradiation 2-5 h before stimulation decreased the characteristic transient expression of E-selectin after TNFalpha stimulation. CONCLUSIONS: Modulation of E-selectin liberation on activated endothelial cells may be one mechanism to decrease leukocyte adhesion after low-dose irradiation in vitro, and could be involved in the therapeutic action of anti-inflammatory radiotherapy.

The influence of autologous tumor fibroblasts on the radiosensitivity of squamous cell carcinoma megacolonies.

PURPOSE: To study the influence of tumor fibroblasts on radiosensitivity and stem cell fraction of tumor cells in squamous cell carcinoma megacolonies by determining colony cure and clonogen survival. METHODS AND MATERIALS: Murine squamous cell carcinoma cells (AT478c) grown as flat but multilayered megacolonies were co-cultured with pre-irradiated tumor fibroblasts derived from the same carcinoma, and irradiated with 1, 2, 4, or 8 fractions. Recurrent clones and their growth pattern in situ were recorded. From megacolony cure data and clonogen survival data, the clonogen number and the parameters of cellular radiosensitivity were calculated. RESULTS: The curability of the co-cultured megacolonies, as determined by TCD50 values, was significantly increased compared to the megacolonies without fibroblasts (p < 0.01). Both the megacolony cure and clonogen survival data suggested a decrease of the clonogen fraction in the co-cultured megacolonies. CONCLUSIONS: The presence of tumor fibroblasts increases megacolony radiosensitivity. This is due to a decrease in the fraction of clonogens in the tumor megacolony, apparently caused by a downregulation of the stem cell fraction of the tumor cells.

The relationship between the RBE of alpha particles and the radiosensitivity of different mutations of Chinese hamster cells.

The RBE of alpha-particles in different mutations of Chinese hamster cells was determined with the aim of identifying differences in the sensitivity to x-ray and alpha-particle-induced DNA damage. Two parental lines of Chinese hamster cells and four radiosensitive mutants were irradiated with different single doses of x-rays and alpha-particles and clonogenic cell survival was determined. Radiosensitivity to x-rays varied by a factor of 5 between the cell strains whereas sensitivity to alpha-particle irradiation was almost identical among all strains. The RBE is only determined by the sensitivity of the cells towards x-rays. Since cells with different defects of repair or cell cycle control have different radiosensitivities, we conclude that the effects of x-ray irradiation and the RBE are mostly determined by the activity of repair processes.

Non-targeted radiation effects in radiotherapy--roles of radiation-induced genomic instability and of the bystander effect in cancer cure by radiotherapy.

Local tumour control by radiotherapy requires the complete sterilization of all tumour 'stem' cells in the tumour volume. Neither bystander effect nor radiation-induced genomic instability is able to contribute substantially to the probability of local tumour control of the primary cancer by radiotherapy. However, the progeny of these surviving tumour 'stem' cells are likely to suffer from radiation-induced genomic instability, which results in the persistent appearance of non-stem cells, i.e. a reduced probability of self-maintenance. This results in a slower growth rate of the recurrent tumour, a reduced stem-cell fraction and, as a consequence, an increased radiosensitivity of the recurrent tumour. In some recurrent tumours, particularly those that develop very late and grow very slowly, radiosensitivity may be further increased by increased intrinsic radiosensitivity, which could be related to the as yet poorly defined phenotype of 'small colony formation'.

[Which methods to minimize the time factor are substantiated by the evidence, which are unproven?]. / Welche Methoden zur Minimierung des Zeitfaktors sind gesichert, welche sind ungesichert?

BACKGROUND: Several experimental studies and randomized clinical trials demonstrate a decrease of local tumor control with increasing overall treatment time of fractionated radiotherapy. Proliferation of clonogenic tumor cells most likely is the major mechanism underlying this phenomenon. Important progress in radiation oncology might therefore be expected from inhibition of proliferation of clonogenic cells during radiation treatment. METHODS: Possibilities to minimize the time factor are briefly discussed. RESULTS AND CONCLUSIONS: Inhibition of proliferation of clonogenic tumor cells during irradiation by simultaneous chemotherapy, by inhibition of signal transduction pathways that stimulate proliferation, or by pharmacological inhibition of angiogenesis are scientifically interesting but currently not proven to be effective to counteract the loss of local tumor control with increasing overall treatment of fractionated irradiation. At present, the only established approach is to complete radiotherapy within a short overall treatment time, e.g. by accelerated fractionation and by prevention or compensation of unscheduled treatment gaps.

Volume effects in radiobiology as applied to radiotherapy.

PURPOSE: To explore the radiobiological evidence for a dependence of normal tissue complication probability on irradiated normal tissue volume. MATERIALS AND METHODS: Data from experimental studies on the volume effect in different organs, using different criteria of structural or functional organ damage and in different animals, were evaluated to investigate the volume effects for structural radiation damage as opposed to functional radiation damage, and the importance of organ anatomy and dose distribution within the organ on the development of chronic radiation damage in the respective organ. RESULTS: There is little or no volume effect for structural radiation damage, however, some very pronounced volume effects have been reported for functional damage. Volume, as such, is not the relevant criterion, since critical, radiosensitive structures are not homogeneously distributed within organs. CONCLUSION: Volume effects in patients and experimental animals are more related to organ anatomy and organ physiology than to cellular radiobiology.

Molecular mechanisms of radiation carcinogenesis and the linear, non-threshold dose response model of radiation risk estimation.

Recent research in molecular radiation carcinogenesis is reviewed with the specific aim of exploring the implications this research may have on the dose response relationship of radiation-induced cancer at low doses and low dose rates. It is concluded that the linear non-threshold dose response hypothesis may be used in radiation protection planning as a simple, convenient method to optimize procedures and regulations, but should not be mistaken as a stringent scientific conclusion directly derived from the present state of knowledge of the processes involved in radiation carcinogenesis.

Chemoradiotherapy interactions and lung toxicity.

BACKGROUND: The combination of high-dose radiotherapy with intensive chemotherapy may improve the prognosis of patients with inoperable, locally advanced non-small-cell lung cancer. In the design of suitable clinical protocols, potential interactions of drugs and radiation in the tumour, the lung and other critical normal tissues have to be considered. METHODS: From experimental data on chemotherapy radiotherapy interactions and based on knowledge about the biology of non-small cell lung cancer and the pathogenesis of radiation pneumopathy, the principles which should be considered in the design of treatment schedules are developed. RESULTS: For the increase in local tumour control, further escalation of radiation dose should be considered first. The most critical issue for lung toxicity may be the volume of the 30 Gy isodose. Yet, the most critical normal tissue which may limit the further increase in dose and dose intensity appears to be the oesophagus. CONCLUSIONS: Since the main cause of treatment failure remains local recurrence, further increase in locoregional cytotoxicity is the first priority in locally advanced non-small-cell lung cancer. This can best be achieved by increasing radiation dose and dose intensity further. Yet, there may also be a role for simultaneous radiochemotherapy, even if this would increase the lung volume which develops radiation pneumopathy and thus the severity of symptoms. This problem should be dealt with by reducing the irradiated lung volume by use of conformal treatment planning. The most critical side effects will then be due to increased severity of acute oesophagitis.

A progress report of the Marshall Islands nationwide thyroid study: an international cooperative scientific study.

The objective of this report is to present a summary of progress of the Marshall Islands Nationwide Thyroid Study. As well known, the US atomic weapons testing program in the Pacific was conducted primarily between 1946 and 1958 in the Marshall Islands. The nuclear tests resulted in radioactive contamination of a number of atolls and resulted in exposure of Marshallese to undefined levels before our study. Little information has been paid to health consequences among residents of the nearly twenty inhibited atolls except for some information about nodular thyroid disease which was reported on by an US group. In a cooperative agreement with the Government of the Marshall Islands, between 1993 and 1997 we studied the prevalence of both thyroid nodules and thyroid cancer among 4766 Marshallese potentially exposed to radioiodines from bomb test fallout. That group represents more than 65% of the population at risk. We diagnosed 45 thyroid cancers and 1398 benign thyroid nodules. In addition, 23 study participants had been operated on prior to our study for thyroid cancer. Presently, we are developing a database of information to estimate radiation doses and planning a statistical analysis to determine if a dose-response relationship exists. These data will be important for the health promotion of exposed people all over the world including Hiroshima, Nagasaki, Semipalatinsk, Chernobyl and other locations. A timely completion is important for purpose of assisting Marshallese as well as to add the global understanding of radiation induced thyroid cancer.

Thyroid nodules, thyroid function and dietary iodine in the Marshall islands.

BACKGROUND: Thyroid nodules have been found to be common in the population of the Marshall Islands. This has been attributed to potential exposure of radioiodines from the nuclear weapons tests on Bikini and Eniwetok between 1946 and 1958. METHODS: In order to get a full picture of thyroid pathology in the Marshallese population potentially exposed to radioactive fallout we performed a large thyroid screening programme using palpation, high resolution ultrasound and fine needle biopsies of palpable nodules. In addition, various parameters of thyroid function (free T3, free T4, thyroid stimulating hormone [TSH]) and anti-thyroid antibodies were examined in large proportions of the total population at risk. Since dietary iodine deficiency is an established risk factor for thyroid nodules, iodine concentration in urine samples of 362 adults and 119 children was measured as well as the iodine content of selected staple food products. RESULTS: The expected high prevalence of thyroid nodules was confirmed. There was no indication of an increased rate of impaired thyroid function in the Marshallese population. A moderate degree of iodine deficiency was found which may be responsible for some of the increased prevalence of thyroid nodules in the Marshallese population. CONCLUSIONS: Studies on the relationship between exposure to radioiodines and thyroid nodules need to take dietary iodine deficiency into account in the interpretation of findings.

Radiobiological mechanisms of anti-inflammatory radiotherapy.

Radiotherapy with total doses of < or =6 Gy has been given as very effective and low risk treatment of painful degenerative joint diseases and other inflammatory processes. Recent radiobiological experiments in vitro and in vivo identified mechanisms which may be related to these anti-inflammatory radiation effects, in particular functional modulation of the adhesion of white blood cells to activated endothelial cells and modulation of the induction of nitric oxide synthase in activated macrophages.

Modulation of accelerated repopulation in mouse skin during daily irradiation.

BACKGROUND AND PURPOSE: The timing of acceleration of repopulation in the epidermis during daily irradiation is related to the development of skin erythema and epidermal hypoplasia. Therefore, the relationship between impairment of the epidermal barrier function, the dermal inflammatory response and epidermal hypoplasia with the acceleration of repopulation was investigated. MATERIALS AND PURPOSE: Skin fields of approximately 1 cm2 on the thighs of TUC mice were given five daily fractions of 3 Gy in each week followed by top-up doses at the end of the first, the second, or the third week to determine residual epidermal tolerance and to calculate repopulation rates in weeks 1, 2, or 3. Systemic modulation of repopulation was attempted by daily indomethacine during fractionated irradiation whereas tape stripping or UV-B exposure before the start of fractionated irradiation attempted local modulation. In parallel experiments, the water permeability coefficient of the epidermis was determined ex vivo by studying transepidermal transport of tritiated water. RESULTS: Without modulation, no repopulation was found in the first week of daily fractionation but repopulation compensated 30% of the dose given in week two and 70% of the dose given in week three. Only tape stripping before the start of fractionated irradiation accelerated repopulation in week one. UV-B had no effect on repopulation although it stimulated proliferation as much as tape stripping. Indomethacin did not suppress acceleration of repopulation. A significant increase in transepidermal water loss was found but only after repopulation had already accelerated. CONCLUSIONS: Acceleration of repopulation in mouse epidermis during daily-fractionated irradiation is not related to the simultaneous development of an inflammatory response. Also, the loss of the epidermal barrier function is not involved in the development of the acceleration response, which rather seems to be triggered directly by the decreased cellularity of the epidermis.

The mechanisms of acceleration of repopulation in squamous epithelia during daily irradiation.

Recent experimental data relating to the mechanisms of accelerated repopulation during daily fractionated irradiation are reviewed. There is evidence indicating that acceleration of repopulation is an active response towards the progressively accumulating radiation damage which is characteristic for squamous cell carcinomas and their tissue of origin, i.e. normal squamous epithelium. Whereas little is known about the mechanisms in tumours, various aspects of the trigger and the biological mechanisms have recently been elucidated in normal squamous epithelium. It is reasonable to expect that some of them might also operate in squamous cell carcinomas. Acceleration is due to the loss of asymmetry of stem cell divisions. This may be associated with changes in the keratinocyte differentiation pattern leading to a functionally defective, parakeratotic and hyperproliferative epithelium. This occurs at a certain level of tissue injury. Although related to the time of incipient erythema, the trigger is not the inflammatory response itself or the functional insufficiency of the irradiated epithelium. Rather, the trigger is directly related to the progressive hypoplasia which causes changes in intercellular communication. There is also evidence that acceleration is modulated by signalling processes between the effector keratinocytes and various mesenchymal cells in the irradiated tissue.