Nonhuman primates as models for the discovery and development of radiation countermeasures

Singh, Vijay K.; Olabisi, Ayodele O.

doi:10.1080/17460441.2017.1323863

Cited by 74 publications

(68 citation statements)

References 125 publications

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“…Despite the signi cant clinical incidence of intestinal radiation injury in cancer patients, effective therapies to address intestinal radiation injury are not available. NHPs seem to reproduce several aspects of acute radiation syndrome (ARS) observed in humans (Reviewed in [20]). In light of similarity to physiological responses to radiation in humans, evolutionary relatedness, similarity in organ structure; GI symptoms and metabolism to humans, NHPs are considered to be the benchmark animal model for studying ARS.…”

Section: Discussionmentioning

confidence: 99%

Changes in the Gut Microbiome Community of nonhuman primate following radiation injury

Kalkeri

Walters

Pol

et al. 2020

Preprint

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Abstract Background Composition and maintenance of the microbiome is vital to gut homeostasis. However, there is limited knowledge regarding the impact of high doses of radiation, which can occur as a result of cancer radiation therapy, nuclear accidents or intentional release of a nuclear or radioactive weapon, on the composition of the gut microbiome. Therefore, we sought to analyze alterations to the gut microbiome of nonhuman primates (NHPs) exposed to high doses of radiation. Methods Fecal samples were collected from 19 NHPs (Chinese rhesus macaques, Macaca mulatta) one day prior and one and four days after exposure to 7.4 Gy cobalt-60 gamma-radiation (LD70 − 80/60). The 16S V4 rRNA sequences were extracted from each sample, followed by bioinformatics analysis using the QIIME platform. Results Alpha Diversity (Shannon Diversity Index), revealed no major difference between pre- and post-irradiation, whereas Beta diversity analysis showed significant differences in the microbiome after irradiation (day + 4) compared to baseline (pre-irradiation). The Firmicutes/Bacteriodetes ratio, a factor known to be associated with disruption of metabolic homeostasis, decreased from 1.2 to less than 1 post-radiation exposure. Actinobacillus, Bacteroides, Prevotella (Paraprevotellaceae family) and Veillonella genera were significantly increased by more than 2-fold and Acinetobacter and Aerococcus genus were decreased by more than 10-fold post-irradiation. Fifty-two percent (10/19) of animals exposed to radiation demonstrated diarrhea at day 4 post-irradiation. Comparison of microbiome composition of feces from animals with and without diarrhea at day 4 post-irradiation revealed an increase in Lactobacillus reuteri associated with diarrhea and a decrease of Lentisphaerae and Verrucomicrobioa phyla and Bacteroides in animals exhibiting diarrhea. Conclusion Our findings demonstrate that substantial alterations in the microbiome composition of NHPs occur following radiation injury and provide insight into early changes with high-dose, whole-body radiation exposure. Future studies will help identify microbiome biomarkers of radiation exposure and develop effective therapeutic intervention to mitigate the radiation injury.

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Section: Discussionmentioning

confidence: 99%

Changes in the Gut Microbiome Community of nonhuman primate following radiation injury

Kalkeri

Walters

Pol

et al. 2020

Preprint

Self Cite

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show abstract

“…Despite the signi cant clinical incidence of intestinal radiation injury in cancer patients, effective therapies to address intestinal radiation injury are not available. NHPs seem to reproduce several aspects of acute radiation syndrome (ARS) observed in humans (Reviewed in [13]). In light of similarity to physiological responses to radiation in humans, evolutionary relatedness, similarity in organ structure; GI symptoms and metabolism to humans, NHPs are considered to be the benchmark animal model for studying ARS.…”

Section: Discussionmentioning

confidence: 99%

Changes in the Gut Microbiome Community of Nonhuman Primate Following Radiation Injury

Kalkeri

Walters

Pol

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

Background: Composition and maintenance of the microbiome is vital to gut homeostasis. However, there is limited knowledge regarding the impact of high doses of radiation, which can occur as a result of cancer radiation therapy, nuclear accidents or intentional release of a nuclear or radioactive weapon, on the composition of the gut microbiome. Therefore, we sought to analyze alterations to the gut microbiome of nonhuman primates (NHPs) exposed to high doses of radiation. Fecal samples were collected from 19 NHPs (Chinese rhesus macaques, Macaca mulatta) one day prior and one and four days after exposure to 7.4 Gy cobalt-60 gamma-radiation (LD70-80/60). The 16S V4 rRNA sequences were extracted from each sample, followed by bioinformatics analysis using the QIIME platform. Results: Alpha Diversity (Shannon Diversity Index), revealed no major difference between pre- and post-irradiation, whereas Beta diversity analysis showed significant differences in the microbiome after irradiation (day +4) compared to baseline (pre-irradiation). The Firmicutes/Bacteriodetes ratio, a factor known to be associated with disruption of metabolic homeostasis, decreased from 1.2 to less than 1 post-radiation exposure. Actinobacillus, Bacteroides, Prevotella (Paraprevotellaceae family) and Veillonella genera were significantly increased by more than 2-fold and Acinetobacter and Aerococcus genus were decreased by more than 10-fold post-irradiation. Fifty-two percent (10/19) of animals exposed to radiation demonstrated diarrhea at day 4 post-irradiation. Comparison of microbiome composition of feces from animals with and without diarrhea at day 4 post-irradiation revealed an increase in Lactobacillus reuteri associated with diarrhea and a decrease of Lentisphaerae and Verrucomicrobioa phyla and Bacteroides in animals exhibiting diarrhea. Conclusions: Our findings demonstrate that substantial alterations in the microbiome composition of NHPs occur following radiation injury and provide insight into early changes with high-dose, whole-body radiation exposure. Future studies will help identify microbiome biomarkers of radiation exposure and develop effective therapeutic intervention to mitigate the radiation injury.

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“…GT3 has been investigated for its radioprotective efficacy against 60 Co c-irradiation using an NHP model with encouraging results (Singh et al 2016b;Singh & Olabisi 2017). GT3 helped the recovery of radiation-induced thrombocytopenia and neutropenia compared to the vehicle controls; these results were especially significant after lethal exposures to 5.8 or 6.5 Gy 60 Co c-TBI.…”

Section: C-tocotrienol (Gt3)mentioning

confidence: 99%

A review of radiation countermeasures focusing on injury-specific medicinals and regulatory approval status: part II. Countermeasures for limited indications, internalized radionuclides, emesis, late effects, and agents demonstrating efficacy in large animals with or without FDA IND status

Singh

Garcia

Seed³

2017

International Journal of Radiation Biology

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The dearth of FDA-approved radiation countermeasures has prompted intensified research for a new generation of radiation countermeasures. A number of promising radiation countermeasures are currently moving forward with continued support and effort by both governmental agencies and by publicly and privately held pharmaceutical companies. There is a limited number of countermeasures which are progressing well following the Animal Rule and may get approved in the near future, thus serving to close the gap of this critically important, unmet radiobiomedical need.

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Nonhuman primates as models for the discovery and development of radiation countermeasures

Cited by 74 publications

References 125 publications

Changes in the Gut Microbiome Community of nonhuman primate following radiation injury

Changes in the Gut Microbiome Community of nonhuman primate following radiation injury

Changes in the Gut Microbiome Community of Nonhuman Primate Following Radiation Injury

A review of radiation countermeasures focusing on injury-specific medicinals and regulatory approval status: part II. Countermeasures for limited indications, internalized radionuclides, emesis, late effects, and agents demonstrating efficacy in large animals with or without FDA IND status

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