Christopher S. Potten

Clonogenic Cells and Stem Cells in Epidermis

A model for epidermal proliferation of a subpopulation of clonogenic cells is briefly discussed and tested in relation to published results of fractionated irradiation survival for mouse epidermis. It is suggested that since the computed average values for the initial number of clonogenic cells differ by an order of magnitude for the measured values for basal cells in mouse skin, one in ten of the basal cells might be clonogenic. It is pointed out that this explanation is compatible with the observation of hexagonal epidermal units, the central stem cell cycling at a slower rate than the rest. (UK)

The detection of cyclobutane thymine dimers, (6-4) photolesions and the Dewar photoisomers in sections of UV-irradiated human skin using specific antibodies, and the demonstration of depth penetration effects

Ultraviolet irradiation of skin induces various DNA photolesions. Here we demonstrate that irradiation of human buttock skin with 300 nm UVR in situ induces thymine dimers and 6-4 photoproducts. Irradiation with 260 nm immediately followed by UVA (320 nm) induces the Dewar photoisomers of the 6-4 lesions. All three lesions can be detected in methanol-fixed paraffin sections using specific monoclonal antibodies. The sections have been analysed in an automated image analysis system (Discovery) and the level of immuno-DAB-peroxidase measured in individual epidermal cell nuclei as absorption at 460 nm (integrated optical density). The staining patterns with the antibodies showed no detectable change with epidermal depth by eye after 300 nm irradiation, however, the machine detected a fall off with depth of about 2.5% per cell layer. Following irradiation with a shorter wavelength (260 nm) there was a rapid fall off in staining with depth easily detectable by eye and machine (39% per cell layer).

Regeneration and Dose–response Characteristics of Irradiated Mouse Dorsal Epidermal Cells

A microcolony technique is described for measuring epidermal cell survival 3 days after whole-body X-irradiation. This assay provides a cell D0 value of 233 +/- 11 rad and a zero-dose extrapolate of 1-23 x 10(4) cells/cm2 for mice irradiated in oxygen 20 hours after hair plucking. The microcolony cellularity had an apparent doubling-time of 25 hours which may be an upper limit at least for some clones. The clones appeared to fragment continually and form new daughter clones, suggesting that few would form macroscopic nodules. Many of the clones were also apparently associated with hair follicles.

The Radiosensitivity of Hair Follicles in Mouse Dorsum and Tail

The radiosensitivity of murine hair follicles was measured in two skin sites, dorsal body and tail. Follicles were considered viable if they appeared histologically similar to controls 4 or 8 weeks after irradiation or similar to growing follicles 12 days after plucking. Dorsal follicles were either unplucked or plucked after and/or before irradiation. Tail follicles were unplucked, but at the time of irradiation the tails were either in air or clamped to induce severe hypoxia, or the mice were anesthetized. The differences in dorsal follicle sensitivity were compared with other widely varying values reported in the literature. The relative sensitivities of the tail follicles in different conditions at the time of irradiation were similar to previous relative sensitivities measured for tail necrosis.

Cell kinetics in rat small intestine after exposure to 3 Gy of gamma-rays at different times of the day.

Qualitative and quantitative morphological changes in rat jejunum were studied after a whole-body exposure to 3 Gy of gamma rays. Four groups of animals were irradiated at different times of the day, namely midnight, 06.00, 12.00 and 18.00 hours. The number of epithelial cells, labelling and mitotic indices were evaluated in crypt sections and the spatial distribution of S-phase cells was determined. At 12 h after irradiation a marked reduction was observed in all parameters, but the proliferative activity was restored quickly and at 36 h after irradiation the values were significantly higher than the controls. The frequency distribution of labelled cells at different positions in the crypt was reduced at 12 h but a clear expansion of S phase cells to positions near to the crypt villus junction was observed during the recovery phase. The animals irradiated at different times of the day showed a similar general post-irradiation response in the number of cells along the side of the crypt, labelling and mitotic indices and in the distribution of S phase cells along the crypts. It is worth noting that the animals exposed at midnight had a distribution of S phase cells similar to controls at 72 h post-irradiation, i.e. earlier than the other groups.

Colonic Cell Proliferation in Normal Mucosa of Patients with Colon Cancer

Cell kinetics parameters have been analysed in colonic mucosa at different distances from a tumour in patients with colon carcinoma. Total cell number (TCN), 3H thymidine labelling index (TLI), mitotic index (MI), Goblet cell index (GCI) and the distribution of labelled cells along the crypt column (cell position frequency plot) were determined in well-aligned crypts. Total cell number, GCI and the labelled cell position frequency plots were similar in different samples from the same individual. A negative linear correlation between TCN and TLI was observed. The analysis of the cell position plots showed two patterns 1) with a high concentration in the bottom fifth of the crypt and 2) with frequent labelled cells at high positions. Whereas a negative correlation between overall TLI and the percent contribution to the TLI of the lowermost fifth was seen, the correlation was positive for the next 3 fifths and labelling was absent in the last part of the crypt.