Melissa Lind scite author profile

Currently, there is a lack of pathological landmarks to describe the progression of prion disease in vivo. Our goal was to use an experimental model to determine the temporal relationship between the transport of misfolded prion protein (PrP Sc ) from the brain to the retina, the accumulation of PrP Sc in the retina, the response of the surrounding retinal tissue, and loss of neurons. Retinal samples from mice inoculated with RML scrapie were collected at 30, 60, 90, 105, and 120 days post inoculation (dpi) or at the onset of clinical signs of disease (153 dpi). Retinal homogenates were tested for prion seeding activity. Antibody staining was used to assess accumulation of PrP Sc and the resulting response of retinal tissue. Loss of photoreceptors was used as a measure of neuronal death. PrP Sc seeding activity was first detected in all samples at 60 dpi. Accumulation of PrP Sc and coincident activation of retinal glia were first detected at 90 dpi. Activation of microglia was first detected at 105 dpi, but neuronal death was not detectable until 120 dpi. Our results demonstrate that by using the retina we can resolve the temporal separation between several key events in the pathogenesis of prion disease. Transmissible spongiform encephalopathies (TSEs) are a family of diseases caused by the accumulation of misfolded prion protein (PrP Sc ). 1 During progression of TSEs, like many protein misfolding disorders, transport of misfolded protein from one central nervous system (CNS) structure seeds protein misfolding and accumulation in another. 2 The details underlying this series of events that begins with the arrival of misfolded protein in a CNS structure and ends with neuronal death in that structure are not well understood. Seeding the brain with an inoculum of misfolded prion protein induces TSEs; thus, these diseases provide a unique opportunity to study the transport of PrP Sc from one CNS structure to another.Currently, there is no treatment for TSEs. Although in silico and in vitro approaches have been effective at identifying compounds with therapeutic potential, 3e8 development of effective therapies would be facilitated by a well-described in vivo model of misfolded protein transport and accumulation, with objective measures of neural degeneration.The retina is part of the CNS and is affected by numerous protein misfolding diseases, including Alzheimer disease, 9 Parkinson disease, 10e12 and numerous TSEs, including scrapie in sheep, 13,14 chronic wasting disease in

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Genetic diseases conferring resistance to infectious diseases

Withrock

Anderson

Jefferson

et al. 2015

Genes & Diseases

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This review considers available evidence for mechanisms of conferred adaptive advantages in the face of specific infectious diseases. In short, we explore a number of genetic conditions, which carry some benefits in adverse circumstances including exposure to infectious agents. The examples discussed are conditions known to result in resistance to a specific infectious disease, or have been proposed as being associated with resistance to various infectious diseases. These infectious disease—genetic disorder pairings include malaria and hemoglobinopathies, cholera and cystic fibrosis, tuberculosis and Tay-Sachs disease, mycotic abortions and phenylketonuria, infection by enveloped viruses and disorders of glycosylation, infection by filoviruses and Niemann–Pick C1 disease, as well as rabies and myasthenia gravis. We also discuss two genetic conditions that lead to infectious disease hypersusceptibility, although we did not cover the large number of immunologic defects leading to infectious disease hypersusceptibilities. Four of the resistance-associated pairings (malaria/hemogloginopathies, cholera/cystic fibrosis, tuberculosis/Tay-Sachs, and mycotic abortions/phenylketonuria) appear to be a result of selection pressures in geographic regions in which the specific infectious agent is endemic. The other pairings do not appear to be based on selection pressure and instead may be serendipitous. Nonetheless, research investigating these relationships may lead to treatment options for the aforementioned diseases by exploiting established mechanisms between genetically affected cells and infectious organisms. This may prove invaluable as a starting point for research in the case of diseases that currently have no reliably curative treatments, e.g., HIV, rabies, and Ebola.

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Residential Land-Use Controls and Land Values: Zoning and Covenant Interactions

Dehring¹,

Lind²

2007

Land Economics

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In Situ Temporospatial Characterization of the Glial Response to Prion Infection

et al. 2019

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Mammalian transmissible spongiform encephalopathies (TSEs) display marked activation of astrocytes and microglia that precedes neuronal loss. Investigation of clinical parallels between TSEs and other neurodegenerative protein misfolding diseases, such as Alzheimer’s disease, has revealed similar patterns of neuroinflammatory responses to the accumulation of self-propagating amyloids. The contribution of glial activation to the progression of protein misfolding diseases is incompletely understood, with evidence for mediation of both protective and deleterious effects. Glial populations are heterogeneously distributed throughout the brain and capable of dynamic transitions along a spectrum of functional activation states between pro- and antiinflammatory polarization extremes. Using a murine model of Rocky Mountain Laboratory scrapie, the neuroinflammatory response to prion infection was characterized by evaluating glial activation across 15 brain regions over time and correlating it to traditional markers of prion neuropathology, including vacuolation and PrPSc deposition. Quantitative immunohistochemistry was used to evaluate glial expression of iNOS and Arg1, markers of classical and alternative glial activation, respectively. The results indicate progressive upregulation of iNOS in microglia and a mixed astrocytic profile featuring iNOS expression in white matter tracts and detection of Arg1-positive populations throughout the brain. These data establish a temporospatial lesion profile for this prion infection model and demonstrate evidence of multiple glial activation states.

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Melissa Lind

Temporal Resolution of Misfolded Prion Protein Transport, Accumulation, Glial Activation, and Neuronal Death in the Retinas of Mice Inoculated with Scrapie

Genetic diseases conferring resistance to infectious diseases

Residential Land-Use Controls and Land Values: Zoning and Covenant Interactions

In Situ Temporospatial Characterization of the Glial Response to Prion Infection

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