[Effect of chronic exposure to low doses of ionized radiation on embryonal development of the Japanese quail]

Experiments on Japanese quail embryogenesis on a background of chronic exposure to gamma- and neutron doses comparable with the doses of ionized radiation inside the orbital space stations Mir and ISS, and exploration vehicles gave evidence that permanent absorption of low gamma-doses (0,15 cgy/d) did not impact development of the Japanese quail embryos. On the contrary, the neutron dose of 200 microgy/d imparted by the neutron flux of 30 particles/cm2s was hazardous to embryos as it caused morphological disorders in 12% of embryos.

Transgenerational transmission of radiation damage: genomic instability and congenital malformation

The congenital malformation gastroschisis has a genetic disposition in the inbred mouse strain HLG/Zte. It is increased after preconceptional irradiation of males or females. Radiation exposures during the meiotic stages are most efficient. This malformation can also be induced by ionising radiation when the exposure takes place during the preimplantation period especially during the zygote stage. This latter effect can be transmitted to the next mouse generation. Other macroscopically visible or skeletal malformations are not significantly induced under these experimental conditions. These latter malformations are increased by radiation exposures during major organogenesis. The mechanisms for the development of the effects are different. Radiation exposure of the mouse zygote (1 to 3 hours p.c.) also leads to the induction of genomic instability in skin fibroblasts of the fetus. This phenomenon also occurs in a mouse strain (C57BL/6J) which is not susceptible to radiation-induced gastroschisis during the preimplantation period. The genomic instability is transmitted to the next mouse generation. During genomic instability chromatide breaks are dominating as in non-exposed cells. With respect to "spontaneous" malformations gastroschisis is dominating in HLG/Zte mice. Late radiation effects seem to have similar patterns as observed in non-exposed subjects, however, the rates are increased after irradiation.

The GABAergic system of the developing neocortex has a reduced capacity to recover from in utero injury in experimental cortical dysplasia

Cortical dysplasia is frequently associated with epilepsy but mechanisms underlying this association are poorly understood. Rats irradiated in utero serve as an injury-based model of cortical dysplasia. Prior studies in mature rats have shown a selective reduction in the number of neocortical interneurons after in utero irradiation. This study attempted to clarify the nature of the radiation injury to the developing neocortical GABAergic system after exposure to gamma-irradiation on the 17th day of gestation (E17). Stereological methods were used to quantify absolute numbers of total neurons (TN) and GABAergic neurons in the neocortex on E21 and postnatal day 6 (P6). In irradiated rats, TN was decreased to about 50% of controls at both time points. However, TN doubled between the 2 time points, even in irradiated animals. In controls, GABAergic neurons increased 10-fold between E21 and P6, but there was no difference in GABAergic counts between the 2 time points in irradiated animals. This led to a dramatic reduction in the percentage of neocortical neurons that were GABAergic in irradiated animals at P6 (9% vs 18%). This study shows that, in contrast to non-GABAergic neurons, the neocortical GABAergic system has a limited capacity to recover from radiation-induced in utero injury.

Adaptive response in embryogenesis. III. Relationship to radiation-induced apoptosis and Trp53 gene status

We reported previously that a radiation-induced adaptive response existed in the late period of embryogenesis, and that radiation-induced apoptosis in the predigital regions was responsible for digital defects in embryonic ICR mice. To investigate the possible involvement of the Trp53 gene and radiation-induced apoptosis in radiation-induced adaptive responses in embryogenesis, the present study was conducted using Trp53 wild-type (Trp53(+/+)) and Trp53 heterozygous (Trp53(+/-)) embryonic mice of the C57BL/6 strain. The existence of a radioadaptive response in the Trp53(+/+) embryonic mice was demonstrated by irradiating the embryos with 5 or 30 cGy on embryonic day 11 prior to a challenging irradiation at 3 Gy on embryonic day 12. The two conditioning doses at 5 and 30 cGy significantly suppressed the induction of apoptosis by the challenging dose in the predigital regions of limb buds in the Trp53(+/+) embryonic mice, while no such effect was found in the Trp53(+/-) embryonic mice. These findings indicate that induction of a radioadaptive response in embryogenesis is related to Trp53 gene status and the occurrence of radiation-induced apoptosis.

Health impacts of large releases of radionuclides. Biological effects of prenatal irradiation

After large releases of radionuclides, exposure of the embryo or fetus can take place by external irradiation or uptake of radionuclides. The embryo and fetus are radiosensitive throughout prenatal development. The quality and extent of radiation effects depend on the developmental stage. During the preimplantation period (one to 10 days postconception, p.c.), a radiation exposure of at least 0.2 Gy can cause the death of the embryo. Malformations are only observed in rare cases when genetic predispositions exist. Macroscopic, anatomical malformations are induced only after irradiation during the major organogenesis (two to eight weeks p.c.). A radiation dose of about 0.2 Gy is a doubling dose for the malformation risk, as extrapolated from experiments with rodents. The human embryo may be more radioresistant. During early fetogenesis (8-15 weeks p.c.) a high radiosensitivity exists for the development of the brain. Radiation doses of 1.0 Gy cause severe mental retardation in about 40% of the exposed fetuses. It must be taken into account that a radiation exposure during the fetal period can also induce cancer. It is generally assumed that the risk exists at about the same level as for children.

[Experience in using cystamine for decreasing radiation disorders in Wistar rat embryogenesis]

In experiments on 340 primigravida Wistar rats and 1557 young rats of the first generation a study was made of toxicity and radioprotective efficiency of single subcutaneous injection of 100 mg/kg cystamine on days 3, 11 and 19 of pregnancy. In the control animals, the preparation caused different changes in the pregnancy course, delivery and postnatal development of posterity. The radioprotective properties of the preparation were only manifested when embryos were exposed to 3 Gy radiation (a lethal dose) during the preimplantation period, and it was less effective during the periods of organogenesis and fetus formation.

[Radiation disorder of enzyme synthesis in the perinatal period of ontogeny]

A change of enzymatic differentiation in the rat liver during the perinatal developmental period after gamma-irradiation on the 7-9th and 19th days of embryogenesis in doses 0.5, 2 and 6 Gr has been shown on the example of glucose-6-phosphatase (G-6-P-ase) and tyrosine aminotransferase (TAT). The protein-synthesizing machinery was not damaged at these doses. The radiation inhibition of G-6-P-ase synthesis was relieved by the injection of thyroxine. A dependence was shown between the radiation increase of TAT activity and changes in cAMP system (increase of cAMP level, decrease of phosphodiesterase activity, intensification of response of adenylate cyclase complex to biogenic amines). A suggestion is put forward that the radiation damage of the enzymes under study is mediated by a change in the number of hormonal inductors.

[Pathogenesis of skeletal radiation injuries to the proximal portion of the pelvic extremity in white rat embryos]

The mechanisms forming certain anomalies in the pelvic proximal part in the offspring of white rats subjected to x-ray radiation on the 12th and 13th days of gestation have been analysed. Serial sections of the embryos performed at various time after radiation and electron microscopic investigations have demonstrated that radiation lesions in the locomotor apparatus are of different pathogenesis. Defects in the femoral and pelvic bones, their fusion in the coxofemoral joint are anomalies resulted from destruction of some mesenchymal cells in the proximal part of the pelvic bud. Femoral dislocation, formed during gestation, is a result of disorders in coordinative muscle development, surrounding the joint and that of hypoplasia in the bursae-ligamentous apparatus (lack of head ligament, hypoplasia of the acetabular lip). Power disbalance in the muscles surrounding the joint is the main course resulting in dislocation of the femoral head.

Palatal shelf epithelium: a morphologic and histochemical study in X-irradiated and normal mice

The palatal shelf epithelium of normal and irradiated mice was examined morphologically and histochemically, utilizing the periodic acid-Schiff (PAS) technique for the demonstration of the basement membrane and the Nitro BT method for succinate dehydrogenase activity in order to demonstrate the metabolic competence of its cells. The 'programmed cell death theory' was not supported by the present investigation, since the cells of the medial ridge epithelium retained their structural and metabolic integrity even subsequent to the formation of cell nests. Additionally, the medial ridge epithelium of mice with radiation-induced cleft palates demonstrated normal structural and metabolic integrity long past the prospective time of fusion.

Radiation damage in mouse embryos exposed to 1 rad x-rays or negative pions

Pregnant mice of two different strains (F/A and NMRI) were exposed to 1 rad of whole-body pion- or X-irradiation at day 8 of gestation. Lucanthone (Miracil D), a known radiosensitizer in various biological systems, was applicated 30 min before irradiation. Five days after treatment the fetuses were observed for developmental anomalies. In both strains of mice it was found that the radiation dose as low as 1 rad results in a significant increase in the rate of abnormal fetuses compared to nonirradiated, but restrained fetuses. Comparing the effectiveness of negative pions (peak irradiation) with X-rays for teratogenic effects, the RBE was between 1.7 and 1.9. The application of Lucanthone increased the number of damaged fetuses and led to various degrees of sensitization depending on the mouse strain and dosage used. Differences between the strains as regards the frequency of damages are explained by different development stages at the time of treatment.