RADIATION DEPIGMENTATION OF MOUSE HAIR: A STUDY OF FOLLICULAR MELANOCYTE POPULATIONS

The radiation depigmentation of mouse hair has been studied by a technique enabling melanocyte per follicle counts to be made. Distributions for normal skin show a large peak corresponding to the zigzag hair type. Changes in the frequency distributions of melanocytes per follicle after irradiation are presented for Strong F and DBA-1 mice irradiated in anagen or telogen stages of hair growth. These distributions clearly suggest the existence of some precursor cells, and the dose-response curves obtained by defining radiation survivors as follicles containing more than ten melanocytes gives the sensitivity of these cells to inactivation. D₀ values are 180–220 rads. A melanocyte-melanoblast model is proposed for the follicular melanocyte cycle which can be outlined as follows: The telogen follicle contains a small number of amelanotic melanocytes that survived through catagen. These cells possess the ability to repopulate the follicle with melanocytes. In catagen functional and/or amelanotic melanocytes are lost at random. Genes for dilution (possibly only when modified by other coat colour genes) and radiation both increase the chance of melanocyte loss at catagen by altering the melanocyte-dermal papilla relationship. One way in which this is affected is by a shortening of the dendrites. A feedback may operate in the follicle so that the full complement of melanocytes is achieved whatever number of melanocytes persists in telogen.     

Molecular cloning and sequencing of a murine pgk-1 pseudogene family

Seven genomic mouse DNA fragments carrying pgk-1-homologous regions have been cloned and sequenced. They have to be classified as processed genes because intervening sequences, present in their productive counterpart, are absent. Four pseudogenes (I-IV) represent nearly the complete sequence of pgk-1 cDNA. Two of these genes (I and II), although rather different from the published mouse pgk-1 cDNA in the 3'-untranslated region, represent the actual mouse pgk-1 cDNA sequence in the coding part except for substitutions in the third position of three codons. These genes can code for a functional PGK protein but, lacking as they do classical promoter structures, are probably not expressed. They show the typical characteristics of retroposons, being flanked by A-rich regions and direct repeats which are localized at the positions where the homology with the mouse pgk-1 cDNA is interrupted. Pseudogenes III and IV have numerous mutations. Gene III is also flanked by direct repeats, whereas gene IV is flanked by inverted repeats. The other three genes are flanked by direct repeats localized further inside the target sites. They are truncated and mutated extensively as usually observed with pseudogenes.     

A CELL KINETIC MODEL TO EXPLAIN THE TIME OF APPEARANCE OF SKIN REACTION AFTER X-RAYS OR ULTRAVIOLET LIGHT IRRADIATION

Skin reactions to various doses of X-rays (300 and 10 kV) and ultraviolet light (u.v.) have been compared using hairless mice. Two regions of epidermis with widely differing cell kinetics and gross structure have been compared. Little evidence could be found to support the idea that the early phases of the reaction are dependent on cell cycle time. The data can be explained by a model based on the assumption that epidermis contains only a small fraction of clonogenic (stem) cells and this fraction may vary in different epidermal regions. X-rays appear to exert their greatest destructive action on these clonogenic cells while u.v. is more indiscriminate in its action, killing both clonogenic and non-clonogenic cells.     

Differential Radiation Response Amongst Proliferating Epithelial Cells

Tissue irradiation results in both reproductive and histologically evident cell death. the correlation between these is poor. Irrespective of dose and fraction sterilized, many cells behave as if unirradiated (cell cycle and maturation activity). the fraction of histologically observable dead cells is usually less than 0.1, with most in the intestine being positioned in the presumptive stem cell region. the data strongly suggest different epithelial sub-populations with differing radioresponses. These may be the stem and differentiated proliferative cells.     

Age Changes in Stem Cells of Murine Small Intestinal Crypts

Cell senescence is seen in many types of differentiated cells but age changes in stem cells have not previously been clearly demonstrated. Changes in stem cells may be of great importance for the ageing process, because any decline with age in the numbers and functional integrity of stem cells can lead to progressive deterioration of function and of proliferative homeostasis in tissues. Stem cells of the murine small intestine provide an excellent model system because these cells occupy a well-defined position near the base of the crypts of Lieberkühn. We examined mice aged between 5 and 32 months and found age-related alterations in the histology of the small intestine and in the apoptotic response of stem cells to low-dose irradiation. Apoptosis in the crypts is concentrated around the stem cell position and can be markedly elevated by exposure to radiation or cytotoxic agents, suggesting that “suicide” of damaged stem cells may be an important system for long-term tissue maintenance. Animals aged 5, 15, 18, and 29 months were exposed to either 1 or 8 Gy gamma irradiation. A twofold increase in the level of apoptosis was seen following 1 Gy gamma irradiation in the 29-month-old animals, compared to the young and middle-age groups. After 8 Gy irradiation the level of apoptosis in all age groups was high and the age effect less pronounced. The data suggest that stem cells do undergo some functional alteration with age.     

Radiation-induced mitotic delay: duration, dose and cell position dependence in the crypts of the small intestine in the mouse

The cells of the proliferative compartment in the crypt of the small intestine undergo a step by step differentiation and/or maturation from stem cells to the functional cells on the villi. The consequent hierarchical organization of the proliferative cell population can be related to the actual position of cells within the crypt. The stem cells are found near the bottom of the crypt with the more mature cells occurring at increasingly higher positions. The sensitivity of proliferative cells in the crypt of small intestine to radiation-induced mitotic delay was investigated at each position within the crypt. Using the stathmokinetic method (vincristine accumulation), the following were noted. The yield of mitotic figures 3 h immediately after irradiation showed a strong cell position dependence with the cells at the base of the crypt being most inhibited and those at the top of the proliferative compartment least affected. The mitotic yields were largely unaffected for the first 15 min suggesting that there is a transition point (Tp) for radiosensitivity which is located about 15 min before metaphase for all crypt cells. Cells located less than 15 min from metaphase are unaffected while those more than 15 min from metaphase are inhibited from further cell cycle progression. After this initial delay all proliferative cells were inhibited in their progression through G2 but some recovered more quickly than others. The ratio of the time of division delay (Td) in stem cells to that in cells at the top of the proliferative compartment was about 3:1. In absolute values Td after 1.0 Gy was about 1 h and 2.8 h, for cells at the top of the crypt and at the base, respectively. After 2.5 Gy the corresponding values were less than 3 h and between 5 and 6 h for the mid-crypt and crypt base respectively. There is thus a dependence on dose for the duration of the mitotic inhibition which for the cells at the top of the crypt is similar to the widely quoted average value 1 h per Gy, but the duration depends strongly on cell position. Thus not all proliferative cells respond in the same way. The duration is shorter the closer the proliferative cells are to their last cell division in the proliferative hierarchy in the crypt and longest for cells situated where the stem cells are to be expected.     

The clonogen content of murine intestinal crypts: dependence on radiation dose used in its determination.

The number of colony-forming (clonogenic) cells in each of the crypts in mouse small intestine was deduced using a two-dose irradiation technique. The number was 7.5 +/- 0.8 cells using two equal doses each less than 9 Gy and 38 +/- 7 cells using 9 Gy or more per dose. The significant dose dependence could not be accounted for by considerations of intra- or intercrypt variability, or by the factor introduced to correct the sampling frequency for the influence of crypt size. The results suggest that more colony-forming cells may be recruited when the injury is more severe.     

The distribution of endocrine cells along the mouse intestine: a quantitative immunocytochemical study

The topographical distribution of endocrine cells in the crypt and villus epithelium along the length of the mouse intestine was studied. Argyrophil reactivity using the Grimelius stain was used to estimate the total endocrine population of the intestine. Comparisons were then made with the fraction of endocrine cells containing glucagon like material, stained immunocytochemically using rabbit anti-glucagon antisera. A highly significant reduction in the incidence of endocrine cells (argyrophil reactive) from the proximal to distal end of the intestine was noted. However, only 10-30% of these cells contained glucagon like material in the crypts of the duodenum, jejunum and ileum, compared to 30-60% in the crypts of the colon and rectum. The distribution of endocrine cells (argyrophil reactive) was maximal in the lower regions of the proliferative zone of the crypts but showed no significant variation along the length of the villi. Cells containing glucagon like material were also most frequent in the lower regions of the proliferative zone of the crypts, but were not generally found above the bottom third of the villi. Each crypt in the small intestine contains between 3 and 5 endocrine cells one of which contained glucagon like immunoreactive material. In the colon and rectum each crypt contains about 6-8 endocrine cells, of which 3-4 contained glucagon like immunoreactive material. These results indicate that a sub-set of cells containing glucagon like material, differentiate early in the lineage of endocrine cells within the proliferative zone of the intestinal crypts.