H3-THYMIDINE AUTORADIOGRAPHIC STUDIES ON CYTOKINETIC RESPONSES TO X-RAY IRRADIATION AND TO THIO-TEPA IN THE NEURAL TUBE OF MOUSE EMBRYOS

How radiosensitive are the developing embryo and fetus?

In its 1990 recommendations, the ICRP considered the radiation risks after exposure during prenatal development. This report is a critical review of new experimental animal data on biological effects and evaluations of human studies after prenatal radiation published since the 1990 recommendations.

Thus, the report discusses the effects after radiation exposure during pre-implantation, organogenesis, and fetogenesis. The aetiology of long-term effects on brain development is discussed, as well as evidence from studies in man on the effects of in-utero radiation exposure on neurological and mental processes. Animal studies of carcinogenic risk from in-utero radiation and the epidemiology of childhood cancer are discussed, and the carcinogenic risk to man from in-utero radiation is assessed. Open questions and needs for future research are elaborated.

The report reiterates that the mammalian embryo and fetus are highly radiosensitive. The nature and sensitivity of induced biological effects depend upon dose and developmental stage at irradiation. The various effects, as studied in experimental systems and in man, are discussed in detail. It is concluded that the findings in the report strengthen and supplement the 1990 recommendations of the ICRP.

Variability and partial synchrony of the cell cycle in the germinal zone of the early embryonic cerebral cortex

Cell cycle parameters were estimated using the cumulative 3H-thymidine S-phase labeling and percentage of labeled mitoses methods in the embryonic day 14 and 15 germinal zone of the rat cerebral cortex. The shortest cell cycle time was seen in the dorsal neocortex and the longest in the lateral neocortex and fimbria (the latter also had a low growth fraction). No differences were observed in cell cycle times between the cells in the ventricular and subventricular zone in the same neocortical region. The results suggest gradients of lengthening cell cycle times extending ventrolaterally and ventromedially from the dorsomedial neocortex. Although a majority of proliferating cells in individual cortical regions seem to belong to one population in terms of cell kinetics, several pieces of evidence suggest some heterogeneity: the asymmetric shapes of the percentages of labeled mitoses curves, the small population of noncycling neuroepithelial cells in the neocortex and mesocortex, and small population of cells that become pyknotic. Groups of DNA-synthesizing nuclei that were ectopically located in the inner half of the ventricular zone also indicate the existence of different subpopulations of neuroepithelial cells. In addition, after a pulse injection of 3H-thymidine the germinal zone is characterized by alternating clusters of heavily and lightly labeled cell nuclei that may reflect the simultaneous passage of a cluster of cells through the same portion of S-phase. We suggest that partial cell cycle synchrony within groups of ventricular cells may explain the presence of these iterative cell kinetic patterns in the developing cortex.

BUdR as an S-phase marker for quantitative studies of cytokinetic behaviour in the murine cerebral ventricular zone

BUdR incorporation into replicating DNA, detected immunohistochemically, is used as an S-phase marker in the proliferative cell populations of the cerebral wall of the mouse embryo on the 14th gestational day (E14). The analysis initiates a series of studies concerned with the cytokinetic behaviour and cell output of proliferative populations involved in neocortical histogenesis. On E14 there are two periventricular proliferative zones in the cerebral wall. These are the ventricular and subventricular zones. The ventricular zone is a pseudostratified epithelium. DNA replication occurs with the cell nucleus in the outer zone of the epithelium and mitoses at the ventricular surface. Prior applications of BUdR for studies of cytogenesis in the CNS have been extended in two principal ways: (1) basic fuchsin was used as counterstain for BUdR-negative nuclei and (2) labelling indices were determined separately in strata or bins, 10 microns in height, through the full depth of the ventricular zone and overlying cerebral wall. It was established that a single injection of 50 micrograms g-1 into the pregnant dam was associated with labelling of 100% of nuclei in S-phase over an interval extending from 15 min to at least 2.0 h after injection. The zone where nuclei are undergoing S-phase (S-phase zone) extends through the outer four bins of the ventricular zone. The method has high quantitative reproducibility with an SE for labelling indices in bins within the S-phase zone less than 10% of the average values. Evidence is provided that BUdR incorporation is initiated with the nucleus in the outer aspect of the S-phase zone. The efficiency of incorporation of the marker is reduced as nuclei near the end of DNA replication and move to the inner aspect of the S-phase zone.

A comparative analysis of [3H]thymidine labeling in the embryonic tectum of the rhesus monkey (Macaca mulatta) and C57BL mouse

The pattern of [3H]thymidine incorporation in the dorsolateral wall of the embryonic tectum was studied and compared one hour after injection of the label in the rhesus monkey (Macaca mulatta) at stages 11-20 (25-37 days of gestation) and in the C57BL mouse at stages 14-22 (9-14 days of gestation). During the early stages of development, the labeled nuclei were located peripherally in the ventricular zone in both the rhesus monkey and mouse embryo, although a number of labeled nuclei tended to occur closer to the ventricular border in the mouse, whereas there was little or no encroachment at the ventricular border in the rhesus monkey. The ventricular zone of the rhesus monkey and mouse embryos initially showed a high labeling index (LI) of about 59% which subsequently declined with increasing age. However, the decline occurred earlier and more precipitously in the rhesus monkey. At stage 17 of the rhesus monkey the LI had dropped to about 42%, whereas it still remained at 59% in the 12-day mouse, and by stage 20 of the monkey the LI was approximately 26%, in contrast to 41% in the stage 22 (14-day) mouse. At stage 20 of the mouse (12 days of gestation) the intermediate zone became much thicker than in the comparable stage (17) of the rhesus monkey, and this discrepancy continued at each successive stage observed in the current study. Also, whereas lamination became apparent in the intermediate zone of the mouse at stage 22, the monkey tectum at a comparable stage (20) was poorly differentiated.

Experimental analysis of embryogenesis of cerebellum in rat. II. Morphogenetic malformations following x-ray irradiation on day 18 of gestation

Rat embryos of 18 days gestation were exposed in utero to 170 R of X-ray irradiation. Embryos were collected six hours, 1, 2, and 3 days after irradiation, and animals of 2-, 6-, 15- and 30-day-old postnatal age were sacrificed. Six hours after irradiation pyknosis of cells was notices in the external granular layer along the posterior aspect of the cerebellum. Neuroblasts, destined to differentiate into Purkinje cells, were found arrested in their migratory path. During subsequent periods of embryogenesis the external granular layer was found recovered, and clustering of the neuroblasts were disorganized and fragmented. This abnormal clustering of neuroblasts was permanent, and the external granular layer followed the same abnormal pattern in its growth. During postnatal development the internal granular layer also was found to follow the abnormal pattern of Purkinje cell layer. These abnormal developmental events were seen to lead to malformed folia in the anterior regions of the cerebellum. In addition to it the cerebellum of X-ray irradiated animals appeared smaller than the normal. Issues having a bearing on the differential radiosensitivity of different cells, factors determining the small size of the cerebellum, and cellular events determining the morphogenetic malformations are discussed.

Early chick neuroretinal responses following direct exposure to methotrexate

Explants of 4.5-day-old chick embryonic neuroretinas with mesenchyme were exposed to Methotrexate (MTX) in medium 199 with embryo extract. Proliferative responses of the cultured neuroretinas were followed radioautographically by administration of 3H-thymidine to the cultures. The DNA synthetic, mitotic and pyknotic responses of the ventricular cells of the neuroretina were followed over a 16-hour period. The responses observed suggested that MTX caused a synchronization of the ventricular cells in the pre-mitotic phases with no direct inhibition of mitosis. Furthermore, prolonged exposure to MTX resulted in the accumulation of labeled pyknotic cells, indicating a decline in the regenerative capacity of the proliferative ventricular cells.

The effect of hyperthermia on the neuroepithelium of the 21-day guinea-pig foetus: histologic and ultrastructural study

Hyperthermia was induced in guinea-pigs on day 21 of gestation by placing them in an incubator set at 42-5 degrees-43-0 degrees C for 1 hr. At intervals thereafter foetuses were removed from the uterus and sections of the telencephalon were prepared for light and electron microscopy. The histologic and ultrastructural appearance of the telencephalon of the normal 21-day guinea-pig foetus was described for comparative purposes. Damage to cells in mitosis characterised by clumping of chromosomes, and dispersal of polysomes in interphase cells were observed immediately after hyperthermia. Breakdown of the network of junctional complexes was apparent at 4 hr and cellular proliferation was inhibited for 6-8 hr. Degenerative changes and cell deaths were observed deep in the venticular zone after 8 hr; the extent of cell death was related to the post-stressing temperature. Proliferation was resumed at 8 hr and damaged and dead cells moved outward toward the intermediate zone. Phagocytosis of debris by large mononuclear cells was a common finding. Cytoplasmic inclusions, some of which were Feulgen-positive, were present in otherwise normal ventricular cells. Occasional dead cells and empty spaces were present in the ventricular zone at 24 hr and by 48 hr the ventricular zone was normal in appearance. It was concluded that previously observed micrencephaly in the offspring of guine-pig mothers which were heat stressed on day 21 of gestation resulted from a temporary cessation of proliferation and partial depopulation of the proliferating neuroepithelium.

Histological effects of 6-mercaptopurine on the fetal rat central nervous system: a light-microscopic study

Wistar rats were administered single doses of 16 or 50 mg/kg 6-mercaptopurine (6-MP) on day 12 of pregnancy. Necrosis in the fetal forebrain and spinal cord was studied by light microscope 6, 12, 14, 48, 72, and 81 h and 8 days afterward. The extent of necrosis was dose dependent. The first necroses were seen after 24 h, regardless of location (brain, spinal cord) or dose; but the extent was greatest after 48 h. All necrotic cells had a typical appearance; they were ballooned and often fragmented, their nuclei were darkly colored and frequently pyknotic, and they were often karyorhexic. Necroses appeared almost exclusively at sites of beginning cellular differentiation, i.e., in the intermediate zone. In the spinal cord the ventricular zone was also necrotic and the alar plate (dorsal horn) always affected. Phagocytizing cells (macrophages) appeared in the spinal cord after 48 h and in the brain after 72 h. After 81 h all the necrotic material had been phagocytized, at which time there was a massive congestion of the extra- and intracerebral vessels. Hemorrhages appeared in defined localizations. Eight days after exposure to 16 mg/kg 6-MP fetuses no longer showed any visible deviations. Fetuses exposed to 50 mg/kg showed deviations in the cytoarchitecture of the neopallium: an extremely broadened ventricular zone, few cells in the intermediate zone, and extensive rarefaction cells in the cortical plate with no clear layer structure. In the spinal cord, cleft formations were especially noticeable in the dorsal-horn region. All fetuses showed a hydrocephalus externus after 50 mg/kg. The mechanism leading to necrosis is discussed.

Quantitative analysis of cell proliferation and differentiation in the cortex of the postnatal mouse cerebellum

The generation cycle of germinative cells (external matrix cells) in the external granular layer of the cerebellar cortex of the 10-to 11-day-old mouse was studied by radioautography following repeated injections of H(3)-thymidine. The generation time is 19 hr, presynthetic time 8.5 hr, DNA-synthetic time 8 hr, postsynthetic time 2 hr, and mitotic time 0.5 hr. These proliferating cells occupy the outer half of the external granular layer and make up the external matrix layer. Neuroblasts are differentiated from the external matrix cell, migrate out from the layer and accumulate in the inner half of the external granular layer to form the external mantle layer. The transit time of the neuroblasts in the external mantle layer is 28 hr. Thereafter, they migrate farther into the molecular layer and the internal granular layer. By means of long-term cumulative labeling, the rate of daily production of neuroblasts from the external matrix cell is studied in quantitative terms. It becomes clear that the entire population of the inner granule neurons arises postnatally in the external granular layer between 1 and 18 days of age and that 95% of them is produced between postnatal days 4 and 15. Finally, the fate of the cells in the external granular layer at its terminal stage was studied by marking the cells with H(3)-thymidine during 15-16 days of life and following their subsequent migration and developmental changes up to 21 days of life. Comparison of radioautographs taken before and after the migration disclosed that the external matrix cells give rise to a small number of neuroglia cells. This finding revealed their multipotential nature.