Effects of Proton and Combined Proton and 56Fe Radiation on the Hippocampus

Raber, Jacob; Allen, Antiño R.; Sharma, Sourabh; Allen, Barrett D.; Rosi, Susanna; Olsen, Reid H.J.; Davis, Michaël I.; Eiwaz, Massarra A.; Fike, John R.; Nelson, Gregory A.

doi:10.1667/rr14222.1

Cited by 79 publications

(71 citation statements)

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“…Only a few studies have examined CFC in young adult mice after HZE-particle exposure, and it is challenging to compare these to our work. For example, young adult mice exposed to protons (150 MeV) have shown increased freezing at low dose (0.1 Gy) with no change at higher doses (0.5, 1 Gy) at 1 month postirradiation, and no change in any group at 3 months postirradiation (27). However, cued FC was not reported as being assessed, so it remains possible that increased freezing at 0.1 Gy proton irradiation was due to anxiety, not improved memory.…”

Section: Discussionmentioning

confidence: 99%

“…Another way to answer this question is to widen the comparison to all studies investigating HZE-induced behavioral changes in young adult mice after exposure to mission-relevant doses (<1 Gy and ideally <0.2 Gy). From this perspective, there is increasing evidence that lower doses of 56 Fe (as low as 0.2 Gy), 28 Si (0.005 Gy), 16 O (0.01 Gy), 12 C (0.05 Gy), protons (0.1 Gy) or combined exposure (e.g., protons and 56 Fe) impede hippocampal, striatal and executive function in young adult rats and mice (9, 27, 91–100) in an energy-dependent manner. Although there is a relative paucity of behavioral studies using 28 Si radiation, our data show that exposure to 0.2 Gy 28 Si radiation induces deficits in hippocampal function even at 3 months postirradiation.…”

Section: Discussionmentioning

confidence: 99%

“…As for CNS function, there is an ion-specific effect on the hippocampal-based learning task, contextual fear conditioning (CFC), where mice learn that a context is associated with a foot shock (25). For example, it has been reported that 2-month-old C57BL/6J mice exposed to 56 Fe (0.1–0.5 Gy) freeze as much as nonirradiated mice in a shock-associated context (26, 27). 56 Fe-exposed mice also freeze similarly to nonirradiated mice in a companion test to CFC, cued fear conditioning (FC), which is both hippocampal-and amygdalar-dependent and whose results can reflect anxiety-like behaviors (26).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Whole-Body Exposure to²⁸Si-Radiation Dose-Dependently Disrupts Dentate Gyrus Neurogenesis and Proliferation in the Short Term and New Neuron Survival and Contextual Fear Conditioning in the Long Term

et al. 2017

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Astronauts traveling to Mars will be exposed to chronic low doses of galactic cosmic space radiation, which contains highly charged, high-energy (HZE) particles. 56Fe-HZE-particle exposure decreases hippocampal dentate gyrus (DG) neurogenesis and disrupts hippocampal function in young adult rodents, raising the possibility of impaired astronaut cognition and risk of mission failure. However, far less is known about how exposure to other HZE particles, such as 28Si, influences hippocampal neurogenesis and function. To compare the influence of 28Si exposure on indices of neurogenesis and hippocampal function with previous studies on 56Fe exposure, 9-week-old C57BL/6J and Nestin-GFP mice (NGFP; made and maintained for 10 or more generations on a C57BL/6J background) received whole-body 28Si-particle-radiation exposure (0, 0.2 and 1 Gy, 300 MeV/n, LET 67 KeV/µ, dose rate 1 Gy/min). For neurogenesis assessment, the NGFP mice were injected with the mitotic marker BrdU at 22 h postirradiation and brains were examined for indices of hippocampal proliferation and neurogenesis, including Ki67+, BrdU+, BrdU+NeuN+ and DCX+ cell numbers at short- and long-term time points (24 h and 3 months postirradiation, respectively). In the short-term group, stereology revealed fewer Ki67+, BrdU+ and DCX+ cells in 1-Gy-irradiated group relative to nonirradiated control mice, fewer Ki67+ and DCX+ cells in 0.2 Gy group relative to control group and fewer BrdU+ and DCX+ cells in 1 Gy group relative to 0.2 Gy group. In contrast to the clearly observed radiation-induced, dose-dependent reductions in the short-term group across all markers, only a few neurogenesis indices were changed in the long-term irradiated groups. Notably, there were fewer surviving BrdU+ cells in the 1 Gy group relative to 0- and 0.2-Gy-irradiated mice in the long-term group. When the short- and long-term groups were analyzed by sex, exposure to radiation had a similar effect on neurogenesis indices in male and female mice, although only male mice showed fewer surviving BrdU+ cells in the long-term group. Fluorescent immunolabeling and confocal phenotypic analysis revealed that most surviving BrdU+ cells in the long-term group expressed the neuronal marker NeuN, definitively confirming that exposure to 1 Gy 28Si radiation decreased the number of surviving adult-generated neurons in male mice relative to both 0- and 0.2-Gy-irradiated mice. For hippocampal function assessment, 9-week-old male C57BL/6J mice received whole-body 28Si-particle exposure and were then assessed long-term for performance on contextual and cued fear conditioning. In the context test the animals that received 0.2 Gy froze less relative to control animals, suggesting decreased hippocampal-dependent function. However, in the cued fear conditioning test, animals that received 1 Gy froze more during the pretone portion of the test, relative to controls and 0.2-Gy-irradiated mice, suggesting enhanced anxiety. Compared to previously reported studies, these data suggest that 28Si-radiation exposure damag...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Whole-Body Exposure to²⁸Si-Radiation Dose-Dependently Disrupts Dentate Gyrus Neurogenesis and Proliferation in the Short Term and New Neuron Survival and Contextual Fear Conditioning in the Long Term

et al. 2017

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“…Sham irradiated mice served as controls and were placed into the same enclosures and for the same amount of time, since previous studies reported no effect of sham irradiation on molecular end-points (Miousse et al, 2014). One week after irradiation, the mice were shipped to Oregon Health and Science University (OHSU) where they underwent behavioral testing reported elsewhere (Raber et al, 2015). Food (PicoLab Rodent Diet 20, no.…”

Section: Methodsmentioning

confidence: 99%

Densely ionizing radiation affects DNA methylation of selective LINE-1 elements

Prior

Miousse

Nzabarushimana

et al. 2016

Environmental Research

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Long Interspersed Nucleotide Element 1 (LINE-1) retrotransposons are heavily methylated and are the most abundant transposable elements in mammalian genomes. Here, we investigated the differential DNA methylation within the LINE-1 under normal conditions and in response to environmentally relevant doses of sparsely and densely ionizing radiation. We demonstrate that DNA methylation of LINE-1 elements in the lungs of C57BL6 mice is dependent on their evolutionary age, where the elder age of the element is associated with the lower extent of DNA methylation. Exposure to 5-aza-2′-deoxycytidine and methionine-deficient diet affected DNA methylation of selective LINE-1 elements in an age- and promoter type-dependent manner. Exposure to densely IR, but not sparsely IR, resulted in DNA hypermethylation of older LINE-1 elements, while the DNA methylation of evolutionary younger elements remained mostly unchanged. We also demonstrate that exposure to densely IR increased mRNA and protein levels of LINE-1 via the loss of the histone H3K9 dimethylation and an increase in the H3K4 trimethylation at the LINE-1 5′-untranslated region, independently of DNA methylation. Our findings suggest that DNA methylation is important for regulation of LINE-1 expression under normal conditions, but histone modifications may dictate the transcriptional activity of LINE-1 in response to exposure to densely IR.

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“…It is now recognised that sufficient doses of ionising radiation can induce microglial activation and pro-inflammatory derived factors which can propagate radiation-induced brain injury [90], [91]. Correspondingly, radiation-induced neuroinflammation can inhibit adult neurogenesis in the hippocampus [92], [93], [94], [95], with longer term cognitive deficits in patients persisting from months to decades after initial exposure [96]. Interestingly, the finding of reversible inhibition of the proliferative capacity of progenitor cells in the dentate gyrus 1 week after 4 Gy X-radiation exposure, with an absence of microglial activation [97], suggests there is a requirement of neuroinflammatory processes to cause persistent and deleterious effects to cells [98].…”

Section: The Impact Of High Dose Ionising Radiation On the Cnsmentioning

confidence: 99%

The impact of high and low dose ionising radiation on the central nervous system

et al. 2016

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Responses of the central nervous system (CNS) to stressors and injuries, such as ionising radiation, are modulated by the concomitant responses of the brains innate immune effector cells, microglia. Exposure to high doses of ionising radiation in brain tissue leads to the expression and release of biochemical mediators of ‘neuroinflammation’, such as pro-inflammatory cytokines and reactive oxygen species (ROS), leading to tissue destruction. Contrastingly, low dose ionising radiation may reduce vulnerability to subsequent exposure of ionising radiation, largely through the stimulation of adaptive responses, such as antioxidant defences. These disparate responses may be reflective of non-linear differential microglial activation at low and high doses, manifesting as an anti-inflammatory or pro-inflammatory functional state. Biomarkers of pathology in the brain, such as the mitochondrial Translocator Protein 18 kDa (TSPO), have facilitated in vivo characterisation of microglial activation and ‘neuroinflammation’ in many pathological states of the CNS, though the exact function of TSPO in these responses remains elusive. Based on the known responsiveness of TSPO expression to a wide range of noxious stimuli, we discuss TSPO as a potential biomarker of radiation-induced effects.

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Effects of Proton and Combined Proton and 56Fe Radiation on the Hippocampus

Cited by 79 publications

References 49 publications

Whole-Body Exposure to²⁸Si-Radiation Dose-Dependently Disrupts Dentate Gyrus Neurogenesis and Proliferation in the Short Term and New Neuron Survival and Contextual Fear Conditioning in the Long Term

Whole-Body Exposure to²⁸Si-Radiation Dose-Dependently Disrupts Dentate Gyrus Neurogenesis and Proliferation in the Short Term and New Neuron Survival and Contextual Fear Conditioning in the Long Term

Densely ionizing radiation affects DNA methylation of selective LINE-1 elements

The impact of high and low dose ionising radiation on the central nervous system

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Effects of Proton and Combined Proton and 56Fe Radiation on the Hippocampus

Cited by 79 publications

References 49 publications

Whole-Body Exposure to28Si-Radiation Dose-Dependently Disrupts Dentate Gyrus Neurogenesis and Proliferation in the Short Term and New Neuron Survival and Contextual Fear Conditioning in the Long Term

Whole-Body Exposure to28Si-Radiation Dose-Dependently Disrupts Dentate Gyrus Neurogenesis and Proliferation in the Short Term and New Neuron Survival and Contextual Fear Conditioning in the Long Term

Densely ionizing radiation affects DNA methylation of selective LINE-1 elements

The impact of high and low dose ionising radiation on the central nervous system

Contact Info

Product

Resources

About

Whole-Body Exposure to²⁸Si-Radiation Dose-Dependently Disrupts Dentate Gyrus Neurogenesis and Proliferation in the Short Term and New Neuron Survival and Contextual Fear Conditioning in the Long Term

Whole-Body Exposure to²⁸Si-Radiation Dose-Dependently Disrupts Dentate Gyrus Neurogenesis and Proliferation in the Short Term and New Neuron Survival and Contextual Fear Conditioning in the Long Term