Your search keyword '"Chase Baune"' showing total 5 results

1. CD11c is not required by microglia to convey neuroprotection after prion infection

Author

James A. Carroll, James F. Striebel, Chase Baune, Bruce Chesebro, and Brent Race

Subjects

Medicine, Science

Published

2023

2. Efficacy of Wex-cide 128 disinfectant against multiple prion strains.

Author

Chase Baune, Bradley R Groveman, Andrew G Hughson, Tina Thomas, Barry Twardoski, Suzette Priola, Bruce Chesebro, and Brent Race

Subjects

Medicine, Science

Abstract

Prion diseases are transmissible, fatal neurologic diseases that include Creutzfeldt-Jakob Disease (CJD) in humans, chronic wasting disease (CWD) in cervids, bovine spongiform encephalopathy (BSE) in cattle and scrapie in sheep. Prions are extremely difficult to inactivate and established methods to reduce prion infectivity are often dangerous, caustic, expensive, or impractical. Identifying viable and safe methods for treating prion contaminated materials is important for hospitals, research facilities, biologists, hunters, and meat-processors. For three decades, some prion researchers have used a phenolic product called Environ LpH (eLpH) to inactivate prions. ELpH has been discontinued, but a similar product, Wex-cide 128, containing the similar phenolic chemicals as eLpH is now available. In the current study, we directly compared the anti-prion efficacy of eLpH and Wex-cide 128 against prions from four different species (hamster 263K, cervid CWD, mouse 22L and human CJD). Decontamination was performed on either prion infected brain homogenates or prion contaminated steel wires and mouse bioassay was used to quantify the remaining prion infectivity. Our data show that both eLpH and Wex-cide 128 removed 4.0-5.5 logs of prion infectivity from 22L, CWD and 263K prion homogenates, but only about 1.25-1.50 logs of prion infectivity from human sporadic CJD. Wex-cide 128 is a viable substitute for inactivation of most prions from most species, but the resistance of CJD to phenolic inactivation is a concern and emphasizes the fact that inactivation methods should be confirmed for each target prion strain.

Published

2023

3. Microglia have limited influence on early prion pathogenesis, clearance, or replication.

Author

Brent Race, Katie Williams, Chase Baune, James F Striebel, Dan Long, Tina Thomas, Lori Lubke, Bruce Chesebro, and James A Carroll

Subjects

Medicine, Science

Abstract

Microglia (MG) are critical to host defense during prion infection, but the mechanism(s) of this neuroprotection are poorly understood. To better examine the influence of MG during prion infection, we reduced MG in the brains of C57BL/10 mice using PLX5622 and assessed prion clearance and replication using multiple approaches that included bioassay, immunohistochemistry, and Real-Time Quaking Inducted Conversion (RT-QuIC). We also utilized a strategy of intermittent PLX5622 treatments to reduce MG and allow MG repopulation to test whether new MG could alter prion disease progress. Lastly, we investigated the influence of MG using tga20 mice, a rapid prion model that accumulates fewer pathological features and less PrPres in the infected brain. In C57BL/10 mice we found that MG were excluded from the inoculation site early after infection, but Iba1 positive infiltrating monocytes/macrophage were present. Reducing MG in the brain prior to prion inoculation did not increase susceptibility to prion infection. Short intermittent treatments with PLX5622 in prion infected C57BL/10 mice after 80 dpi were unsuccessful at altering the MG population, gliosis, or survival. Additionally, MG depletion using PLX5622 in tga20 mice had only a minor impact on prion pathogenesis, indicating that the presence of MG might be less important in this fast model with less prion accumulation. In contrast to the benefits of MG against prion disease in late stages of disease, our current experiments suggest MG do not play a role in early prion pathogenesis, clearance, or replication.

Published

2022

4. Reduced SOD2 expression does not influence prion disease course or pathology in mice

Author

Simote T. Foliaki, Brent Race, Katie Williams, Chase Baune, Bradley R. Groveman, and Cathryn L. Haigh

Subjects

Medicine, Science

Abstract

Prion diseases are progressive, neurodegenerative diseases affecting humans and animals. Also known as the transmissible spongiform encephalopathies, for the hallmark spongiform change seen in the brain, these diseases manifest increased oxidative damage early in disease and changes in antioxidant enzymes in terminal brain tissue. Superoxide dismutase 2 (SOD2) is an antioxidant enzyme that is critical for life. SOD2 knock-out mice can only be kept alive for several weeks post-birth and only with antioxidant therapy. However, this results in the development of a spongiform encephalopathy. Consequently, we hypothesized that reduced levels of SOD2 may accelerate prion disease progression and play a critical role in the formation of spongiform change. Using SOD2 heterozygous knock-out and litter mate wild-type controls, we examined neuronal long-term potentiation, disease duration, pathology, and degree of spongiform change in mice infected with three strains of mouse adapted scrapie. No influence of the reduced SOD2 expression was observed in any parameter measured for any strain. We conclude that changes relating to SOD2 during prion disease are most likely secondary to the disease processes causing toxicity and do not influence the development of spongiform pathology.

Published

2021

5. Reduced SOD2 expression does not influence prion disease course or pathology in mice

Author

Katie Williams, Chase Baune, Brent Race, Bradley R. Groveman, Cathryn L. Haigh, and Simote T. Foliaki

Subjects

Male, Pathology, Antioxidant, medicine.medical_treatment, animal diseases, Scrapie, Pathogenesis, Disease, Pathology and Laboratory Medicine, Biochemistry, Animal Diseases, Prion Diseases, Oxidative Damage, Mice, Medical Conditions, Zoonoses, Medicine and Health Sciences, Brain Damage, skin and connective tissue diseases, Mice, Knockout, chemistry.chemical_classification, Brain Diseases, Antioxidant Therapy, Multidisciplinary, biology, Pharmaceutics, Long-term potentiation, Animal Models, Immunohistochemistry, Electrophysiology, Animal Prion Diseases, Infectious Diseases, Neurology, Experimental Organism Systems, Toxicity, cardiovascular system, Medicine, Research Article, medicine.medical_specialty, Science, Blotting, Western, SOD2, Mouse Models, Research and Analysis Methods, Superoxide dismutase, Model Organisms, Drug Therapy, medicine, Animals, Superoxide Dismutase, Biology and Life Sciences, Mice, Mutant Strains, nervous system diseases, Enzyme, chemistry, Animal Studies, biology.protein, Zoology

Abstract

Prion diseases are progressive, neurodegenerative diseases affecting humans and animals. Also known as the transmissible spongiform encephalopathies, for the hallmark spongiform change seen in the brain, these diseases manifest increased oxidative damage early in disease and changes in antioxidant enzymes in terminal brain tissue. Superoxide dismutase 2 (SOD2) is an antioxidant enzyme that is critical for life. SOD2 knock-out mice can only be kept alive for several weeks post-birth and only with antioxidant therapy. However, this results in the development of a spongiform encephalopathy. Consequently, we hypothesized that reduced levels of SOD2 may accelerate prion disease progression and play a critical role in the formation of spongiform change. Using SOD2 heterozygous knock-out and litter mate wild-type controls, we examined neuronal long-term potentiation, disease duration, pathology, and degree of spongiform change in mice infected with three strains of mouse adapted scrapie. No influence of the reduced SOD2 expression was observed in any parameter measured for any strain. We conclude that changes relating to SOD2 during prion disease are most likely secondary to the disease processes causing toxicity and do not influence the development of spongiform pathology.

Published

2021