Decreased Weight, DNA, RNA and Protein Content of the Brain after Neutron Irradiation of the 18-day Mouse Embryo

Antal, Sára; Fónagy, A; Fülöp, Zoltán; Hidvégi, Egon J.; Vogel, Howard H.

doi:10.1080/09553008414551621

Cited by 15 publications

(8 citation statements)

References 21 publications

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“…However, there was not a good correlation between the reduction of the glutaminase activity and that of glutamine utilization, which was decreased by only 21.4%. It is noteworthy that, taking a dry weight/protein ratio equal to 1.3 (Antal et al, 1984), in both control and glutaminase-deficient mice, flux through glutaminase represented only 0.7% and 1.1% (with 5 mmol/L [3-13 C]glutamine) and 0.3% and 0.4% (with 1 mmol/L [3-13 C]glutamine) of the corresponding maximal glutaminase activity measured in brain homogenates of these mice (Gaisler-Salomon et al, 2009). Thus, despite this, our study shows that a reduction of the maximal activity of glutaminase in the brain is accompanied by a reduction of flux through glutaminase.…”

Section: Characteristics Of Glutamine Metabolism In Brain Slices Frommentioning

confidence: 99%

Brain Slices from Glutaminase-Deficient Mice Metabolize Less Glutamine: A Cellular Metabolomic Study with Carbon 13 NMR

Hage¹,

Masson

Conjard-Duplany

et al. 2012

J Cereb Blood Flow Metab

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In the brain, glutaminase is considered to have a key role in the provision of glutamate, a major excitatory neurotransmitter. Brain slices obtained from wild-type (control) and glutaminase-deficient (GLS1 + /À) mice were incubated without glucose and with 5 or 1 mmol/L [3-13 C]glutamine as substrate. At the end of the incubation, substrate removal and product formation were measured by both enzymatic and carbon 13 nuclear magnetic resonance ( 13 C-NMR) techniques. Slices from GLS1 + /À mice consumed less [3-13 C]glutamine and accumulated less [3-13 C]glutamate. They also produced less 13 CO 2 but accumulated amounts of 13 C-aspartate and 13 C-gamma-aminobutyric acid (GABA) that were similar to those found with brain slices from control mice. The newly formed glutamine observed in slices from control mice remained unchanged in slices from GLS1 + /À mice. As expected, flux through glutaminase in slices from GLS1 + /À mice was found diminished. Fluxes through all enzymes of the tricarboxylic acid cycle were also reduced in brain slices from GLS1 + /À mice except through malate dehydrogenase with 5 mmol/L [3-13 C]glutamine. The latter diminutions are consistent with the decreases in the production of 13 CO 2 also observed in the slices from these mice. It is concluded that the genetic approach used in this study confirms the key role of glutaminase for the provision of glutamate.

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Section: Characteristics Of Glutamine Metabolism In Brain Slices Frommentioning

confidence: 99%

Brain Slices from Glutaminase-Deficient Mice Metabolize Less Glutamine: A Cellular Metabolomic Study with Carbon 13 NMR

Hage¹,

Masson

Conjard-Duplany

et al. 2012

J Cereb Blood Flow Metab

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“…Several studies have demonstrated that prenatal exposure to low-LET radiation induced abnormalities of the developing brain such as cerebral hypoplasia [5][6][7] and neuronal cell death 8,9 , and deceleration of neuronal migration 10,11 in rodents. As for neutrons, Vogel and his colleagues examined the changes of brain in mice prenatally exposed to 0.5 Gy of fission neutrons [12][13][14] , and showed that the body weight and the brain weight decreased induced in the irradiated mice 12,13 . Regarding the mechanism, they showed that the damage to the brain of the fetus after neutron irradiation was mainly due to killing and /or inhibition of the differentiation of neuroblasts 13 , and inhibition of protein synthesis was also observed in the irradiated brain 14 .…”

mentioning

confidence: 99%

“…As for neutrons, Vogel and his colleagues examined the changes of brain in mice prenatally exposed to 0.5 Gy of fission neutrons [12][13][14] , and showed that the body weight and the brain weight decreased induced in the irradiated mice 12,13 . Regarding the mechanism, they showed that the damage to the brain of the fetus after neutron irradiation was mainly due to killing and /or inhibition of the differentiation of neuroblasts 13 , and inhibition of protein synthesis was also observed in the irradiated brain 14 . Although, their studies revealed the important mechanisms concerned in the abnormalities of developing brain induced by prenatal irradiation with neutrons, the dose-response relationships and mechanisms of the biological effects of prenatal exposure to neutrons in comparison with those of low-LET radiation have not yet been clarified.…”

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confidence: 99%

“…5 G y o f f i s s i o n n e u t r o n s w i t h contamination of 0.18 Gy of gamma-rays at E17, and showed remarkable decreases of the brain weight and the body weight in the irradiated mice, however the postnatal histopathological changes of the affected brains were not been determined. Antal et al 13 focused on the early events in the cerebrum of the fetuses, and they hypothesized that pycnotic nuclei, inhibition of mitosis in neuroblasts, and cell death observed in the brains 6 hours after irradiation were the major changes in prenatal irradiation-induced cerebral hypoplasia in mice. Inouye et al 10 presented that the inhibition of neuronal migration during the brain development by low-dose of low-LET radiation participated in cerebral hypoplasia induced in mice.…”

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confidence: 99%

“…The histopathological differences from those reports may be related to the strain difference or type of radiation. Vogel et al 12 and Antal et al 13 examined the abnormalities of brain development in BDF1 mice i r r a d i a t e d w i t h 0 . 5 G y o f f i s s i o n n e u t r o n s w i t h contamination of 0.18 Gy of gamma-rays at E17, and showed remarkable decreases of the brain weight and the body weight in the irradiated mice, however the postnatal histopathological changes of the affected brains were not been determined.…”

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confidence: 99%

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Postnatal Changes in Mice Exposed In Utero to Fast Neutrons

et al. 2004

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Exposure to radiation during brain development stage cause microcephaly or mental retardation. Although X-and gamma-rays induced cerebral hypoplasia in rodents has been well characterized, little is known about such effects of neutrons. To examine the effects of prenatal exposure to neutrons on the development of brain and other organs, both male and female B6C3F1 mice were irradiated with fast neutrons (0.1, 0.2, 0.5, 1 Gy) or gamma-rays (0.8, 1.5 Gy) at embryonic day 13.5, and the animals were examined histopathologically 56 days after birth. Both types of radiation mainly caused hypoplasia of the cerebral cortex and lowered brain absolute weight. No sex differences were seen. These changes were remarkable in each highest dose group. The weight loss of the brain was noted at the lowest dose group of neutrons. In addition, the weight loss of the thymus, atrophy of the seminiferous tubules, and a decrease in follicles of the ovary were also noted in the higher dose groups of neutrons and gamma-rays. The degrees of these changes were larger for neutrons. (J Toxicol Pathol 2004; 17: 63-68)

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Lack of adaptive response of gamma radiation for protection against neutron‐induced teratogenesis

Lee

Kim

Song

et al. 2008

Birth Defects Research Pt B

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Decreased Weight, DNA, RNA and Protein Content of the Brain after Neutron Irradiation of the 18-day Mouse Embryo

Cited by 15 publications

References 21 publications

Brain Slices from Glutaminase-Deficient Mice Metabolize Less Glutamine: A Cellular Metabolomic Study with Carbon 13 NMR

Brain Slices from Glutaminase-Deficient Mice Metabolize Less Glutamine: A Cellular Metabolomic Study with Carbon 13 NMR

Postnatal Changes in Mice Exposed In Utero to Fast Neutrons

Lack of adaptive response of gamma radiation for protection against neutron‐induced teratogenesis

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