Mitotic activity in the blastema and stump tissues of regenerating hind limbs of Xenopus laevis larvae after amputation at ankle level. An autoradiographic study

Mitotic activity, as indicated by DNA synthesis, was studied by autoradiographic analysis along the proximodistal axis of regenerating limbs in the early and later larval stages 53 and 57 of Xenopus laevis. Wound-healing, dedifferentiation, blastema formation and growth phases were studied. Most of the various stump tissues, as well as the cell mass of the regeneration blastema, were involved. The study showed an increase in DNA synthesis in the stump tissues during their dedifferentiation as well as during blastema formation. The increase was confined mainly to the distal portion (close to the amputation level), so that a proximodistal gradient was discernible. This could be regarded as valid evidence of contribution of the severed stump tissues to the blastema cells. The mesenchymal blastema cells formed after amputation at stage 53 displayed higher mitotic activity than the fibrocytoid blastema cells formed at stage 57. Although the latter were more differentiated than the former, they still showed DNA replication and mitotic division.     

Phosphorylated histone H2AX foci persist on rejoined mitotic chromosomes in normal human diploid cells exposed to ionizing radiation

Histone H2AX is phosphorylated and forms foci in response to exposure to ionizing radiation. It has been thought that phosphorylated histone H2AX foci reflect unrepaired DNA double-strand breaks; however, we report here the localization of phosphorylated histone H2AX foci at the site of rejoined DNA double-strand breaks. We observed that phosphorylated histone H2AX foci remained even 96 h after exposure to X rays in interphase cells. To clarify the localization of residual phosphorylated histone H2AX foci, we examined localization of focus formation on mitotic chromosomes irradiated with X rays. We found that phosphorylated histone H2AX foci were located not only on chromosomal fragments but also on intact metaphase chromosomes without fragments. In anaphase cells, chromosomal bridges, which resulted from illegitimate rejoining of DNA broken ends, had phosphorylated histone H2AX foci. These foci were detected as individual small spots 30 min after X irradiation, but foci detected 20 or 96 h after X irradiation were clustered along the chromosomal bridges. These results indicate that phosphorylated histone H2AX foci persist if DNA breaks are rejoined. It is suggested that "residual" foci indicate an aberrant chromatin structure by illegitimate rejoining but not a DNA double-strand break itself.     

Chromosome aberrations induced in vitro by low doses of radiation: nondisjunction in lymphocytes of young adults.

Epidemiological studies suggest radiation exposure as a cause of meiotic non-disjunction in humans, but experimental evidence with cytological proof has been lacking. Our results indicate that mitotic nondisjunction of lymphocyte chromosomes can also be induced by exposure to a low dose of radiation. Abnormal segregation can be induced not only when the cells are irradiated but also when nonirradiated cells are incubated with irradiated cell-free plasma or serum. The X and no. 21 chromosomes appear particularly susceptible to nondisjunction.     

Development of irradiated tunicate buds: Is cell division cycle required for morphallaxis?

In the tunicate, Polyandrocarpa misakiensis , transdifferentiation occurs in the multipotent atrial epithelium during morphallactic bud development. Irradiation (10–80 Gy) or aphidicolin (10 μg/mL) blocked this process severely, although the atrial epithelium could form organ placodes. The placodes consisted of cuboidal cells with a high nucleus : cytoplasm ratio and were lacking the alkaline phosphatase antigen from the cell surface, suggesting that the atrial epithelium might undergo dedifferentiation without initiating cell cycling. Irradiated buds could resume organogenesis in temporal accordance with the restoration of mitotic activity. Bud pieces irradiated at 40 Gy were juxtaposed with unirradiated counterparts. In the operated buds, irradiated, non-dividing cells participated in organogenesis at the site of juxtaposition in cooperation with the unirradiated, dividing cells. These results have shown that in P. misakiensis the cell division cycle, probably DNA replication, is indispensable for transdifferentiation of the atrial epithelium, although every cell in the organ rudiment need not enter cell cycling. We suggest that homoiogenetic induction occurs between dividing cells and non-dividing cells.     

The irradiated epidermis inhibits newt limb regeneration by preventing blastema growth. A histological study

It has been established that X-ray irradiation localized to a forelimb or entire irradiation of premetamorphic Pleurodeles larvae prevented limb regeneration. Transplantation of non-irradiated skin, dermis or muscle to limb stumps of locally irradiated newts was sufficient to allow a blastema to develop. Transplantation of the same tissues to limb stumps of entirely irradiated newts yielded different results with the different graft types. Skin graft allowed a normal blastema to be established but dermis or muscle grafts did not. In order to define more precisely the role played by the epidermis in the establishment of a blastema, and in the growth of a regenerate, different combinations of limb tissues, either irradiated or not, were carried out at the level of amputated limb stumps. At four different times (8-10 days; 13-15 days; 20-23 days; 30 days or more) after amputation the stumps were examined in histological longitudinal sections to study the first events of regeneration, that is dedifferentiation and growth. Dedifferentiation occurred in both normal and irradiated tissues of mesodermal origin. The healthy mesenchymal cells began dividing and formed a growing blastema only when associated with a non-irradiated epidermis. Healthy mesenchymal cells covered with an irradiated epidermis exhibited a few mitoses after dedifferentiation, but the mitotic figures became rarer and rarer until the animals died. The lack of dense accumulation of blastemal cells in such limb stumps suggested that the healthy epidermis allows the mesenchymal cells to divide actively to constitute a growing blastema. Hence, X-ray irradiation seems to be responsible for the loss of such an epidermal mitogenic influence on the underlying mesenchymal cells.     

Effects on adult newt limb regeneration of partial and complete skin flaps over the amputation surface.

The influence of the wound epithelium on the cellular events preceding blastema formation was examined by comparing dedifferentiation, DNA labeling indices, and mitotic indices of the distal mesodermal tissues in control regenerating newt forelimbs and in amputated forelimbs covered with a flap of full thickness skin. Three kinds of results were seen following the skin-flap graft operations. Epidermal migration across the amputation surface was completely inhibited in 22% (8) of the cases and these limbs repaired the amputation wound but did not form regeneration blastemas. In 11% (4) of the experimental limbs, essentially normal wound epithelia displaced the skin flaps and the limb stumps formed blastemas and regenerated. The majority of the skin grafts (67%) exhibited epidermal migration restricted to the free edges of the flaps. These limbs formed eccentric blastemas on the ventral side of the limb next to the dermis-free epidermis and regenerated laterally in that direction.     

Mitotic activity and nucleic acid precursor incorporation in denervated and innervated limb stumps of axolotl larvae.

Mitotic activity and DNA and RNA precursor incorporation were compared in innervated regenerating limbs and in denervated, non-regenerating limbs on days 8 and 9 post-amputation. Innervated limbs had well-developed cone stage blastemas which showed high cellular mitotic indices and H3-thymidine labeling indices of 0.40-0.50 and H3-uridine labeling indices of 0.50-0.75. In contrast, denervated limbs showed dedifferentiated cells distally under thickened wound epithelia, but essentially no mitotic activity and no blastema formation. These dedifferentiated cells showed lower levels of H3-thymidine (0.10 index) and H3-uridine (0.50) incorporation than regenerating limbs. Labeling indices of wound epithelia are also compared.     

Lens formation from cornea implanted into amputated hindlimbs of Xenopus laevis larvae requires innervation or proliferating cell populations in the stump

The capacity of amputated early and late limbs of larval Xenopus laevis to promote lens-forming transformations of corneal implants in the absence of a limb regeneration blastema has been tested by implanting outer cornea fragments from donor larvae at stage 48 (according to Nieuwkoop and Faber 1956), into limb stumps of larvae at stage 52 and 57. Blastema formation has been prevented either by covering the amputation surface with the skin or by reconnecting the amputated part to the limb stump. Results show that stage 52 non-regenerating limbs could promote lens formation from corneal implants not only when innervated but also when denervated. A similar result was observed in stage 57 limbs where blastema formation was prevented by reconnecting the amputated part to the stump. In this case, relevant tissue dedifferentiation was observed in the boundary region between the stump and the autografted part of the limb. However, stage 57 limbs, where blastema formation was prevented by covering the amputation surface with skin, could promote lens formation from the outer cornea only when innervated. In this case, no relevant dedifferentiation of the stump tissues was observed. These results indicate that blastema formation is not a prerequisite for lens-forming transformations of corneal fragments implanted into amputated hindlimbs of larval X. laevis and that lens formation can be promoted by factors delivered by the nerve fibres or produced by populations of undifferentiated or dedifferentiated limb cells.     

Repair of DNA double-strand breaks in colcemid-arrested mitotic Chinese hamster cells

Chinese hamster V79 cells blocked in mitosis were irradiated with 60Co gamma-rays and incubated for repair in the presence of colcemid. DNA strand breaks were measured using neutral sucrose gradient centrifugation or the alkaline unwinding technique. It was found that mitotic cells repair DNA double-strand breaks (as well as single-strand breaks) efficiently, with a rate similar to exponentially growing asynchronous cells. It is argued that the dense packing of the chromatin in the mitotic chromosome makes a recombinational repair mechanism unlikely.     

Transgenerational transmission of radiation induced genomic instability

Stability of genome is one of the evolutionary important trait of cells. Various mutations (gene, chromosomal, genomic) as well as artificial manipulations with genomes (inbreeding, DNA transfection, introduction of Br-DU in DNA) cause the genetic instability. Ionizing radiation is known as the factor which induced instability of genome in late mitotic descendants of cells after in vitro and in vivo exposure. Radiation induced genetic instability can be transmitted through germline cells. On the cell level both types of radiation induced genomic instability are manifested in elevated frequency of mutations, chromosome aberrations, micronuclei, increased radiosensitivity, disappearance of adaptive response, changes in gene expression. In studies of 1970-1980 years clear evidences on the different morphological and functional injuries in tissues of irradiated organisms as well as in tissues of the progeny of exposed parents were obtained. On the organism level the instability of mitotic and of meiotic progeny of irradiated cells is resulted in increased risk of cancer and of other somatic diseases. It seems to be useful to review the earlier radiobiology literature where delayed and transgenerational effects of ionizing radiation on tissues and on organisms level were clearly shown in animals. For the estimation of pathogenic role of radiation induced genomic instability in humans, particularly in children of exposed parents the parallel study of the same human cohorts using clinical parameters and various characteristic of genomic instability seems to be very important.     

Mechanism of functional adaptation of intestinal epithelial cells]

Using preparations of exogenous DNA and products of its in complete degradation, the causes leading to the compensatory changes of the share of membrane hydrolysus in the total invertase activity of the irradiated rat's intestinal epithelial were analysed experimentally. It is shown that the factor stimulating the enzyme redistribution towards the brush border zone is not the amount of mature villous cells, but the level of mitotic activity in crypts.     

Effect of prenatal X irradiation on chemical components of DNA and DNA-protein crosslinks in rat cerebrum in the perinatal periods

Wistar rats were X-irradiated in utero with 100 or 200 R on Day 13 of gestation. X Irradiation resulted in decreases not only in cerebral weight up to 15 days old but also in DNA content from Day 19 of gestation to 5 days old, and in a tendency to increase the ratio of protein to DNA in the perinatal period. The DNA contents of the homogenate, isolated nuclei, and chromatin of the cerebrum in the irradiated group were significantly lower than those in the control group. The ratio of protein to DNA at the nuclei, chromatin, and isolated DNA steps increased on irradiation. The total nucleoside content of isolated DNA determined by high-performance liquid chromatography was higher in the irradiated group than that in the control group on Day 21 of gestation but not on Day 19 of gestation. No new peaks were observed and no change in the guanine-cytosine content was seen on irradiation. X Irradiation resulted in decreases in the cytosine and deoxycytidine contents and an increase in the deoxyadenosine content. The formation of DNA-protein crosslinks in the cerebral chromatin as determined by a filter binding assay tended to increase in the irradiated groups.     

The complexity of DNA double strand break is a crucial factor for activating ATR signaling pathway for G2/M checkpoint regulation regardless of ATM function

DNA double strand break (DSB) repair pathway choice following ionizing radiation (IR) is currently an appealing research topic, which is still largely unclear. Our recent paper indicated that the complexity of DSBs is a critical factor that enhances DNA end resection. It has been well accepted that the RPA-coated single strand DNA produced by resection is a signaling structure for ATR activation. Therefore, taking advantage of high linear energy transfer (LET) radiation to effectively produce complex DSBs, we investigated how the complexity of DSB influences the function of ATR pathway on the G2/M checkpoint regulation. Human skin fibroblast cells with or without ATM were irradiated with X rays or heavy ion particles, and dual-parameter flow cytometry was used to quantitatively assess the mitotic entry at early period post radiation by detecting the cells positive for phosphor histone H3. In ATM-deficient cells, ATR pathway played a pivotal role and functioned in a dose- and LET-dependent way to regulate the early G2/M arrest even as low as 0.2 Gy for heavy ion radiation, which indicated that ATR pathway could be rapidly activated and functioned in an ATM-independent, but DSB complexity-dependent manner following exposure to IR. Furthermore, ATR pathway also functioned more efficiently in ATM-proficient cells to block G2 to M transition at early period of particle radiation exposure. Accordingly, in contrast to ATM inhibitor, ATR inhibitor had a more effective radiosensitizing effect on survival fraction following heavy ion beams as compared with X ray radiation. Taken together, our results reveal that the complexity of DSBs is a crucial factor for the activation of ATR pathway for G2/M checkpoint regulation, and ATM-dependent end resection is not essential for the activation.     

No elevated cell surface charge at mitosis in X-ray-irradiated mammalian cells

Rounded mitotic cells showed 30% enhanced electrophoretic mobility (EPM) when compared to spindle-formed interphase cells. This increase in EPM that was not present in interphase cells that had been rounded chemically by EDTA is considered to reflect a structural change in the cell membrane during mitosis. X-ray irradiation induced a dose-dependent EPM decrease in both interphase and mitotic cells during a 4-hour period. During the next 20 h of incubation, EPM recovery took place in cells irradiated with 250R, but not in cells exposed to 1000R. EPM was enhanced during mitosis in cells irradiated with low doses, but was absent in cells irradiated with 1000R. The ratio of colony-forming cells and of electrophoretically recovered mitotic cells after 24 h of exposure showed a good statistical correlation. These results indicate that unrepaired membrane damage contributes to mitotic cell death after irradiation.     

THE EFFECT OF A MEDIUM DOSE (430 ROENTGENS) OF X-RAY IRRADIATION ON RESTING CELLS OF THE LIVER

The mitotic activity of regenerating liver cells after a single dose (430 r) of x-ray irradiation was studied. In every group of the experimental animals (white rats), the mitotic activity (mitotic index) and the number of abnormal mitotic figures were determined. The results indicated that resting cells irradiated a short time before mitotic activity showed reactions similar to those of cells irradiated during mitotic activity. The disturbances in the irradiated mitotically active cells were only quantitatively different from those in the irradiated resting cells. The disturbances in the irradiated resting cells depended upon the time interval between the irradiation and the beginning of mitotic activity stimulated by partial hepatectomy. It was found that the shorter the time interval, the more pronounced were the disturbances and the more similar they became to those of irradiated mitotically active cells. Conversely, the longer the time interval between the irradiation and the beginning of mitotic activity, the less pronounced were the disturbances and the more similar they became to those of the non-irradiated control cells. A discussion is presented as to whether or not the lesions of resting cells caused by a single medium dose of x-ray irradiation are reversible, and whether such lesions are only brought to light by the process of mitosis or whether the process of mitosis renders it possible for these lesions to develop.     

A test of the punctuated-cycling hypothesis in Ambystoma forelimb regenerates: the roles of animal size, limb innervation, and the aneurogenic condition

The punctuated-cycling (PC) hypothesis [39] predicts that the proportion of actively cycling (AC) cells within the blastema influences the rate of limb regeneration in urodele amphibians. To test this, we compared the rate of regeneration and the parameters of the PC hypothesis in small and large Ambystoma mexicanum larvae and in aneurogenic limbs of Ambystoma maculatum. Aneurogenic limbs regenerated more slowly than limbs of small axolotls, but considerably faster than limbs of large axolotls. Regardless of regeneration rates, virtually all blastema cells were in the proliferative fraction (Pf) (ranging from 92.3% +/- 4.2% to 96.2% +/- 3.4%). As predicted, in the blastemata of more rapidly regenerating small axolotls, 86% of the proliferative fraction was actively cycling, but as regeneration slowed, the proportion of the proliferative fraction that was actively cycling decreased (the AC of aneurogenic limbs being 69.5%, and that of large axolotl limbs being 57.3%) and the proportion of transiently quiescent cells increased. The parameters of the PC hypothesis were also examined in small axolotls at two different times during regeneration. During dedifferentiation and initial blastema formation, 61% of the cells in the proliferative fraction were actively cycling and 34% were transiently quiescent. During the rapid-growth phase of the blastema, 88% of the cells in the proliferative fraction were actively cycling and only 7% of the cells were transiently quiescent. It therefore appears that dedifferentiated cells do not immediately begin active cycling and that the transiently quiescent population is relatively large; however, during the period of rapid growth the proportion of transiently quiescent cells is small. In amputated/denervated limbs of small axolotls, the size of the proliferative fraction decreased as the length of the denervation interval increased. Furthermore, with prolonged denervation the total proportion of actively cycling blastema cells also declined (to about 15%). The failure of denervated limbs to regenerate was correlated with an increased nonproliferative fraction and a reduced proportion of actively cycling cells.     

Megabase chromatin domains involved in DNA double-strand breaks in vivo.

The loss of chromosomal integrity from DNA double-strand breaks introduced into mammalian cells by ionizing radiation results in the specific phosphorylation of histone H2AX on serine residue 139, yielding a specific modified form named gamma-H2AX. An antibody prepared to the unique region of human gamma-H2AX shows that H2AX homologues are phosphorylated not only in irradiated mammalian cells but also in irradiated cells from other species, including Xenopus laevis, Drosophila melanogaster, and Saccharomyces cerevisiae. The antibody reveals that gamma-H2AX appears as discrete nuclear foci within 1 min after exposure of cells to ionizing radiation. The numbers of these foci are comparable to the numbers of induced DNA double-strand breaks. When DNA double-strand breaks are introduced into specific partial nuclear volumes of cells by means of a pulsed microbeam laser, gamma-H2AX foci form at these sites. In mitotic cells from cultures exposed to nonlethal amounts of ionizing radiation, gamma-H2AX foci form band-like structures on chromosome arms and on the end of broken arms. These results offer direct visual confirmation that gamma-H2AX forms en masse at chromosomal sites of DNA double-strand breaks. The results further suggest the possible existence of units of higher order chromatin structure involved in monitoring DNA integrity.     

The effect of the UV microirradiation of the centrosome on cell behavior. III. The ultrastructure of the centrosome after irradiation]

One of the spindle poles of mitotic PK cells was irradiated with UV microbeam in metaphase or in anaphase. Electron microscopy showed that immediately after irradiation the microtubules around the centrosome were maintained, and that the ultrastructure of both irradiated and nonirradiated poles was similar. After microirradiation of the centrosome in metaphase, the mitotic halo around this centrosome was retained, but in due time the number of microtubules was getting less compared to that around the nonirradiated centrosome. When daughter cells with irradiated centrosomes are passing into the interphase, their centrioles are not separated from each other, no primary cilia are formed, and no replication of centrioles occurs. In the interphase cells with irradiated centrosomes, satellites are formed on the active centriole, but centrosome-attached microtubules are practically absent.     

Mitotic recombination in the absence of synaptonemal complexes in Saccharomyces cerevisiae.

Summary Mitotic cells of a diploid strain of Saccharomyces cerevisiae with appropriate markers for the detection of mitotic crossing-over and mitotic gene conversion were irradiated with X-rays. Induction of these recombinational events was strong. After irradiation, cells were incubated in a rich growth medium and samples were removed for studying the possible formation of synaptonemal complexes up to a time when most cells had completed the first post-irradiation cell division. No complexes were found during the entire period of sampling, during which mitotic recombination in G₁ (mitotic gene conversion), DNA replication and G₂ (mitotic crossing-over) had occurred. These results are interpreted to mean that synaptonemal complexes are not required for mitotic recombination.     

The effects of X rays on BCNU-induced DNA crosslinking

We have used the technique of alkaline elution to study DNA interstrand crosslinking in 9L rat brain tumor cells treated with combinations of 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) and X rays. Irradiation with doses as low as 50 rad of X rays immediately or 6 hr after a 1-hr treatment with 60, 80, or 100 microM BCNU produced a significant increase in BCNU-induced DNA interstrand crosslinking. If cells were irradiated before BCNU treatment, the amount of crosslinking was not affected compared with BCNU alone. Cell survival experiments using 600 rad of X rays and 1-hr treatments with 0-30 microM BCNU were also performed. As found in the crosslinking studies, irradiation immediately or 6 hr after the BCNU treatment produced enhanced cell kill, but irradiation 6 hr before BCNU treatment did not produce enhanced cell kill. Therefore, the X-ray-mediated increase in BCNU-induced DNA interstrand crosslinking may be the mechanism through which cell kill is increased by combination treatment with the agents.