When mammalian cells are irradiated in vitro, the component cells of a normal-appearing survivor colony or clone are commonly thought to have proliferative capacity equivalent to that of the unirradiated cells. We have found, however, that cells appearing in survivor colonies may carry heritable lethal defects which come to light, perhaps only after numerous successful divisions, in the form of plating efficiencies that are reduced below those of unirradiated cells in a dose-dependent manner. We regard these heritable defects as signs of the induction of lethal mutations, which, like non-lethal mutations, may require many generations before they are expressed. This effect has been noted in two very dissimilar mammalian cell lines, one a primary culture from adult tissue, the other an immortal cell line. We suggest that induction of lethal mutations may occur also in somatic cells in vivo; this would account for the well-known observation that previously irradiated but apparently healed tissue is subsequently proved to be extraordinarily sensitive to subsequent exposure to irradiation or cytotoxic drugs. The results of our experiments in vitro suggest that current methods of estimating mutation or transformation yields may yield underestimates. If lethal mutations are induced also in vivo, interpretations of the results of fractionation experiments on normal tissues may have to be reconsidered.
The ureter primary explant technique was developed to study bystander effects under in vivo like conditions where stem and differentiated cells are present. Irradiation was performed with a 3He2+ charged particle microbeam available at the Gray Cancer Institute, with high (approximately 2 microns) precision. Tissue sections from porcine ureters were pre-irradiated with the microbeam at a single location with 10 3He2+ particles (5 MeV; LET 70 keV.micron-1). After irradiation, the tissue section was incubated for 7 days, thus allowing the explant outgrowth to form. Total cellular damage (total fraction of micronucleated and apoptotic cells) was measured according to morphological criteria. Apoptosis was also assessed using a 3'-OH DNA end-labelling technique. Premature differentiation was estimated using antibodies to uroplakin III, a specific marker of terminal urothelial differentiation. Results of our experiments demonstrated a significant bystander-induced differentiation and a less significant increase in apoptotic and micronucleated cells. A hypothesis based on the protective nature of the bystander effect is proposed.
The intrinsic radiation sensitivity of normal and tumour tissue is a major determinant of the outcome of radiotherapy. There is currently no established test that can be used routinely to measure the radiosensitivity of the cells in an individual patient's cancer in a manner that can inform treatment planning. The purpose of this study was to evaluate, in four human colorectal adenocarcinoma cell lines, two possible end points as surrogate markers of radiation response -apoptosis and induction of DNA single-strand breaksand to compare the results with those of a conventional clonogenic assay. Cell lines (SW707 SW480, SW48 and HT29) known to differ in radiosensitivity were exposed to single doses of X-rays ranging from 0.5 to 5 Gy and cell survival was measured using the clonogenic assay. Apoptosis was determined on the basis of morphology under fluorescent microscopy and DNA damage/repair was measured, as tail moment, using an adaptation of the alkaline comet assay. The relationship between surviving fraction at 2 Gy (SF 2 ) and the percentage of apoptotic cells 24 h after the same dose was complex, but apoptosis accurately predicted the order of radiosensitivities as measured by SF 2 . Initial damage measured after 2 Gy using the alkaline comet assay gave a close correlation with SF 2 (r 2 ¼ 0.95), whereas there was no correlation between initial DNA damage repair rate and SF 2 .
Immunocytochemical detection of p53 protein products in paraffin sections is possible with a number of antisera, monoclonal and polyclonal. Few corroborative results amongst different laboratories have been published due to variations in the antibodies, the fixation protocols, and the immunocytochemical methods applied. Antigen unmasking methods employing microwaves or proteolytic enzymes add to the disparity in the percentage of positive cases reported. In this study, paraffin sections of 55 cases of cervical carcinoma were immunostained with monoclonal antibodies p53-DO7 and p53-1801 (a) without section pretreatment, (b) with pronase digestion, and (c) with microwave antigen retrieval in citric acid buffer. Specimens fixed in buffered formalin required antigen unmasking to show positive staining. Pronase digestion caused false-negative immunostaining. Microwave pretreatment with p53-DO7 yielded 100 per cent positivity for p53 proteins but only 7/55 cases with more than 50 per cent positive cells. Monoclonal antibody p53-DO7 detected more positive cases than p53-1801. Immunostaining with antibodies to p53 proteins must be interpreted cautiously as variations in fixation, antibodies, and section pretreatment will significantly affect results.
Post-mortem glycolysis was investigated at several locations in intact sides of beef. The time required for the pH to fall to 6.0 in six major hindquarter muscles ranged from 2.2 to 13.6 h, varying with muscle and depth in the carcass. A good correlation (r=0.97) was observed between the rate of ATP turnover and muscle temperature. In the muscles in the round the rate of glycolysis increased with depth, as did the extent of denaturation of myofibrils, creatine phosphokinase and also drip loss.
Growth and a number of differentiated characteristics of cultured epidermal cells from the rainbow trout Oncorhynchus mykiss were compared using two commercially available serumfree media, a dermal substrate/serum free kit and a serum-containing medium which had been previously optimized for epidermal cell culture. Each medium supported short term growth over 15 days. Only the medium supplied for dermal substrate culture supported longer growth periods. This medium was supplied for use with a collagen/stromal substrate but gave good cultures even without the substrate. Differentiation, measured by examining mucous cells, cytokeratins, epidermal growth factor receptor, gap junction status and ultrastructure showed that serum-free media gave quantitatively and qualitatively superior expression and short term retention of differentiation over serum-containing medium. Epithelial cell growth with expression of differentiated characteristics can be maintained in primary culture in serum-free medium for at least as long as in serum-containing medium. This provides a useful technique for use when serum presence in medium is undesirable or proves toxic to the specialized cell type under investigation.
Pathbase is a database that stores images of the abnormal histology associated with spontaneous and induced mutations of both embryonic and adult mice including those produced by transgenesis, targeted mutagenesis and chemical mutagenesis. Images of normal mouse histology and strain-dependent background lesions are also available. The database and the images are publicly accessible (http://www.pathbase.net) and linked by anatomical site, gene and other identifiers to relevant databases; there are also facilities for public comment and record annotation. The database is structured around a novel ontology of mouse disorders (MPATH) and provides high-resolution downloadable images of normal and diseased tissues that are searchable through orthogonal ontologies for pathology, developmental stage, anatomy and gene attributes (GO terms), together with controlled vocabularies for type of genetic manipulation or mutation, genotype and free text annotation for mouse strain and additional attributes. The database is actively curated and data records assessed by pathologists in the Pathbase Consortium before publication. The database interface is designed to have optimal browser and platform compatibility and to interact directly with other web-based mouse genetic resources.
Recently there has been considerable interest in various delayed effects of radiation. These have the common property of showing a high and, in some instances, non-clonal transmission of 'damage' to distant progeny which derive from apparently normal surviving cells and their descendants. This means that conventional analysis and interpretation of long-term radiation damage in terms of mutations induced in DNA at the time of radiation exposure may be incorrect. Several reviews of this area have appeared in recent years which have described the historical development of this field. The aim of this commentary is to highlight areas of discussion, particularly concerning links between the various end-points, and to discuss some of the possible implications of genomic instability for radiation carcinogenesis in general and for the setting of radiation protection action limits in particular.
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