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27 results on '"Theriault, Betty R."'

1. Microbial Colonization of Germ‐Free Mice Restores Neointimal Hyperplasia Development After Arterial Injury

Author

Chen, Edmund B, Shapiro, Katherine E, Wun, Kelly, Kuntz, Thomas, Theriault, Betty R, Nooromid, Michael J, Leone, Vanessa A, Harris, Katharine G, Jiang, Qun, Spedale, Melanie, Xiong, Liqun, Gilbert, Jack A, Chang, Eugene B, and Ho, Karen J

Subjects
Aging, Cardiovascular, Atherosclerosis, Heart Disease, Prevention, Aetiology, 2.1 Biological and endogenous factors, Animals, Carotid Arteries, Carotid Artery Injuries, Disease Models, Animal, Fecal Microbiota Transplantation, Gastrointestinal Microbiome, Germ-Free Life, Hyperplasia, Male, Mice, Inbred C57BL, Neointima, microbiome, neointimal hyperplasia, restenosis, Cardiorespiratory Medicine and Haematology
Abstract

Background The potential role of the gut microbiome in cardiovascular diseases is increasingly evident. Arterial restenosis attributable to neointimal hyperplasia after cardiovascular procedures such as balloon angioplasty, stenting, and bypass surgery is a common cause of treatment failure, yet whether gut microbiota participate in the development of neointimal hyperplasia remains largely unknown. Methods and Results We performed fecal microbial transplantation from conventionally raised male C57BL/6 mice to age-, sex-, and strain-matched germ-free mice. Five weeks after inoculation, all mice underwent unilateral carotid ligation. Neointimal hyperplasia development was quantified after 4 weeks. Conventionally raised and germ-free cohorts served as comparison groups. Conclusions Germ-free mice have significantly attenuated neointimal hyperplasia development compared with conventionally raised mice. The arterial remodeling response is restored by fecal transplantation. Our results describe a causative role of gut microbiota in contributing to the pathogenesis of neointimal hyperplasia.

Published
2020

6. Commensal bacteria protect against food allergen sensitization

Author

Stefka, Andrew T., Feehley, Taylor, Tripathi, Prabhanshu, Qiu, Ju, McCoy, Kathy, Mazmanian, Sarkis K., Tjota, Melissa Y., Seo, Goo-Young, Cao, Severine, Theriault, Betty R., Antonopoulos, Dionysios A., Zhou, Liang, Chang, Eugene B., Fu, Yang-Xin, and Nagler, Cathryn R.

Published
2014

14. Development of early-stage type 1 diabetes in germ-free interleukin-10 deficient mice

Author

Bobe, Alexandria M., primary, Miyoshi, Jun, additional, Moore, Patrick, additional, Devkota, Suzanne, additional, Leone, Vanessa, additional, Martinez, Kristina, additional, Theriault, Betty R., additional, Musch, Mark W., additional, Wasserfall, Clive, additional, Atkinson, Mark, additional, Rhodes, Christopher J., additional, and Chang, Eugene B., additional

Published
2020
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18. Microbiota control acute arterial inflammation and neointimal hyperplasia development after arterial injury

Author

Wun, Kelly, primary, Theriault, Betty R., additional, Pierre, Joseph F., additional, Chen, Edmund B., additional, Leone, Vanessa A., additional, Harris, Katharine G., additional, Xiong, Liqun, additional, Jiang, Qun, additional, Spedale, Melanie, additional, Eskandari, Owen M., additional, Chang, Eugene B., additional, and Ho, Karen J., additional

Published
2018
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19. Mutual reinforcement of pathophysiological host-microbe interactions in intestinal stasis models

Author

Touw, Ketrija, primary, Ringus, Daina L., additional, Hubert, Nathaniel, additional, Wang, Yunwei, additional, Leone, Vanessa A., additional, Nadimpalli, Anuradha, additional, Theriault, Betty R., additional, Huang, Yong E., additional, Tune, Johnathan D., additional, Herring, Paul B., additional, Farrugia, Gianrico, additional, Kashyap, Purna C., additional, Antonopoulos, Dionysios A., additional, and Chang, Eugene B., additional

Published
2017
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20. Hematopoietic stem cell transplantation (HSCT)

Author

Kamiya, Shigeru, Kato, Shunichi, Huang, Xiaojun, Ichinohe, Tatsuo, Konishi, Kiyoshi, Takahashi, Yukihiro, Mikelsaar, Marika, Louis, Petra, Ando, Kiyoshi, Takayama, Naoya, Takahashi, Satoshi, Fasth, Anders, Norin, Elisabeth, Chuang, Hsiao-Li, Huang, Yen-Te, Hou, Chia-Chung, Huang, Chi-Chang, Alexopoulos, Athanasios, Chatzivassiliou, Elisabeth, Plessas, Stavros, Alexakoudi, Maria, Theodoridou, Irene, Fournomiti, Maria, Mantzourani, Ioanna, Voidarou, Chryssa, Stavropoulou, Elizabeth, Bezirtzoglou, Eugenia, Komai, Michio, Shirakawa, Hitoshi, Mikulska, M., Bono, V. Del, Raiola, A.M., Bruno, B., Gualandi, F., Occhini, D., Grazia, C. di, Bacigalupo, A., Frassoni, Francesco, Viscoli, C., Mori, Shinichiro, Taniguchi, Shuichi, Hibi, Toshifumi, Hisamatsu, Tadakazu, Kanai, Takanori, Kiyono, Hiroshi, dos Santos, Liliane M., Hand, Timothy, Bouladoux, Nicolas, Belkaid, Yasmine, Koga, Yasuhiro, Kariyama, Reiko, Kumon, Hiromi, Qu, Di, Wu, Yang, Han, Shiqing, Shen, Xu, Jiang, Hualiang, Yonezawa, Hideo, Taguchi, Haruhiko, Kurata, Satoshi, Arae, Ken, Onogawa, Tsuyoshi, Lin, Michael M.Y., Ota, Yoshinori, Yoshino, Manabu, Annaka, Toshimitus, Notomi, Tsugunori, Kanda, Hidetoshi, Suvorov, Alexander, Simanenkov, Vladimir, Ermolenko, Elena, Kolodjieva, Viktoria, Tcapieva, Anna, Zaharova, Natalia, Solovieva, Olga, Boyko, Nadiiya Volodymyrivna, Syukur, Sumaryati, Hidayat, Habibi, Purwati, Endang, Theriault, Betty R., Olivares, Christina, Vest, Alan, Langan, George P., and Lee, Hoon Taek

Subjects
Symposium Presentations, Bacteriocin, gene of 16S rRNA, Weissella cibiria, Supplement 1, 2012, Lactic acid bacteria, Yellow Marquisa (Passiflora edulis var. Flavicarpa)
Published
2012

23. INDUCTION, MAINTENANCE, AND REVERSAL OF STREPTOZOTOCIN-INDUCED INSULIN-DEPENDENT DIABETES MELLITUS IN THE JUVENILE CYNOMOLGUS MONKEY (Macaca fascilularis)1

Author

Theriault, Betty R., primary, Thistlethwaite, J. R., additional, Levisetti, Matteo G., additional, Wardrip, Craig L., additional, Szot, Gregory, additional, Bruce, David S., additional, Rilo, Horatio, additional, Li, Xiantang, additional, Gray, Gary S., additional, Bluestone, Jeffrey A., additional, and Padrid, Philip A., additional

Published
1999
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24. The Host-specific Microbiota is Required for Diet-Specific Metabolic Homeostasis.

Author

Fei N, Xie B, Long TJ, StGeorge M, Tan A, Manzoor S, Sidebottom AM, Spedale M, Theriault BR, Sulakhe D, and Chang EB

Abstract

In complex mammals, the importance and host-specificity of microbial communities have been demonstrated through their positive effects on host immune fitness or performance. However, whether host metabolic physiology homeostasis depends on a specific bacterial community exclusive to the host remains unclear. Here, we show that the coevolved host-specific microbiota is required to maintain diet-specific flexible and sufficient metabolic homeostasis through a high colonization rate, modulating gut metabolites, and related targets. Using germ-free (GF) mice, we tested whether the fitness benefiting the host metabolic phenotype of microbiota was host-specific. We demonstrated that GF mice associated with exogenous microbiota (human microbiota (HM)), which exhibited different and reduced gut microbial species diversity, significantly elevated metabolic rate, and exhibited metabolic insufficiency, all characteristics of GF mice. Strikingly, the absence of the host-specific microbiome attenuated high-fat diet-specific metabolism features. Different diets caused different metabolic changes in only host-specific microbiota-associated mice, not the host-microbiota mismatched mice. While RNA sequencing revealed subtle changes in the expression of genes in the liver, GF mice and HM mice showed considerably altered expression of genes associated with metabolic physiology compared to GF mice associated with host-specific microbiota. The effect of diet outweighed microbiota in the liver transcriptome. These changes occurred in the setting of decreased luminal short-chain fatty acids (SCFAs) and the secondary bile acid (BAs) pool and downstream gut signaling targets in HM and GF mice, which affects whole-body metabolism. These data indicate that a foreign microbial community provides little metabolic benefit to the host when compared to a host-specific microbiome, due to the colonization selection pressure and microbiota-derived metabolites dysfunction. Overall, microbiome fitness effects on the host metabolic phenotype were host-specific. Understanding the impact of the host-specificity of the microbiome on metabolic homeostasis may provide important insights for building a better probiotic., Highlights: Microbiome fitness effects on the host metabolic phenotype were host-specific in mammals.Human microbiota-associated mice exhibited lower host metabolic fitness or performance, and similar functional costs in GF mice.Different diets cause different metabolic changes only in host-specific microbiota-associated mice, not the host-microbiota mismatched mice.The defective gut microbiota in host-specific microbiota, microbial metabolites and related targets likely drive the metabolic homeostasis.

Published
2023
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25. Preference of Escaped Mice for Live Capture or Glue Traps and Relevance to Pest Control Programs.

Author

Schoenberger JM, Prendergast BJ, Luchins KR, Theriault BR, and Langan GP

Subjects
Animals, Mice, Insecta, Behavior, Animal, Pest Control instrumentation
Abstract

Insects are potential disease vectors for research animals. Therefore, implementing an effective pest control program is an essential component of any animal care and use program. The Guide for the Care and Use of Laboratory Animals emphasizes the humane use of traps; however, insect traps commonly use glue that can entrap escaped research mice, leading to their potential distress and injury. This situation is challenging for research facilities attempting to identify insect populations. In an effort to improve pest control in animal facilities, we sought to characterize the behavioral interactions of mice with common vermin traps. Three experiments using different combinations of traps (glue trap, live mouse trap with a clear viewing window, and live mouse trap with a red-tinted viewing window) were used in multiple behavioral testing arenas to address these questions. Experiments 1 and 2 were performed in a small arena, and Experiment 3 was performed in a simulated mouse housing room. Dependent measures included exploration of the test environment, grooming behavior, time spent near each trap, and latency to capture. Results indicate that mice were captured significantly more quickly by live traps than by glue traps, and were far more likely to enter a live trap as compared with a glue trap. Mice did not appear to differentiate between clear or red-tinted window live traps. Taken together, the results indicate that deploying both a live trap and a glue trap will allow humane capture of escaped mice yet will also capture insects in the same environment.

Published
2023
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26. Identification and Control of an Ornithonyssus Bacoti Infestation in a Rodent Vivarium by Using Molecular Diagnostic Techniques.

Author

Clancy BM, Theriault BR, Schoenberger JM, Bowers CJ, Mitchell CM, Langan GP, Ostdiek AM, and Luchins KR

Subjects
Animals, Delayed-Action Preparations, Mice, Molecular Diagnostic Techniques, Permethrin, Rodentia, Dermatitis etiology, Mite Infestations diagnosis, Mite Infestations epidemiology, Mite Infestations prevention & control, Mites, Pyrethrins
Abstract

Ornithonyssus bacoti , commonly known as the tropical rat mite, is a zoonotic ectoparasite that occasionally infests research rodent colonies. Most infestations have been attributed to wild rodents that harbor the mite and spread it to research animals, often during building construction or other activity that disrupts wild rodent populations. Although infestation may be clinically silent, severe outbreaks have been reported to cause pruritis, dermatitis, decreased reproductive performance, and anemia in rodents. In mid-2020, our institution experienced increased activity of wild mice, which were found to be infested with O. bacoti , diagnosed by microscopic exam and confirmed by fur swab PCR analysis. We elected to add O. bacoti to our quarterly health monitoring exhaust air dust (EAD) testing PCR panel, increase wild mouse control measures, and treat the environment with a sustained-release synthetic pyrethroid spray in an attempt to prevent colony animal infestation. Initial quarterly EAD health monitoring results in September of 2020 were negative for O. bacoti . However, in early 2021, multiple IVC racks tested positive for O. bacoti at quarterly testing. Treatment consisted of providing permethrin-soaked nesting material and surface spray treatment of the room and hallway with a sustained-release synthetic pyrethroid. Historically in the literature, O. bacoti outbreaks of research mice were not identified until mite burden was high enough to cause dermatitis on animal care workers. Due to modern molecular diagnostics and proactive PCR-based health monitoring surveillance, we were able to identify the outbreak earlier than would have otherwise been possible. To the best of our knowledge, this is the first report to successfully identify O. bacoti using environmental health monitoring PCR techniques. This outbreak demonstrates the importance of screening for O. bacoti in facilities with the potential for wild rodent infestation and highlights unique considerations when managing O. bacoti infestations. In addition, a novel permethrin-soaked enrichment item was developed for cage-level treatment.

Published
2022
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