Alexander disease (AxD) is a rare and fatal neurological disorder caused by mutations in the gene that encodes glial fibrillary acidic protein (GFAP), an intermediate filament protein found in astrocytes in the central nervous system. The clinical presentations of AxD are diverse, ranging from onset in infancy to onset in early adulthood, and include seizures, psychomotor retardation, ataxia, and a variety of neurological signs related to abnormal brain stem function. The defining neuropathological hallmark is the presence of cytoplasmic, proteinaceous inclusions called Rosenthal fibers in astrocytes. Although GFAP expression is astrocytic, AxD patients also show de/dysmyelination and variable amounts of neuronal loss, most severely in infantile-onset patients. Astrocytes undergo severe morphological changes, beyond that of typical reactive astrocytes, and develop several forms of cell stress. However, how stressed astrocytes cause the loss of myelin in this disease is unknown. In this work I have conducted a largely immunohistological investigation of AxD patient tissue, model mice, and primary astrocytes cultured from the AxD model mice, focusing on factors that might provide insight into the pathological manifestations of AxD and paying particular attention to those factors which might contribute to de/dysmyelination. To gain insight on the morphological transformation of astrocytes in AxD, I analyzed GFAP in the hippocampus of the most severely affected AxD mouse. Astrocytes in these mice lose their star-like shape, and become hypertrophic and often multinucleated. They accumulate large amounts of GFAP. Subsequent study of primary cultured astrocytes from AxD mice revealed that these cells have perinuclear inclusions of GFAP surrounded by displaced microtubules and displaced Golgi. I next investigated another mechanism of stress that may affect astrocyte function in AxD. Work in our lab and others' has demonstrated proteasomal inhibition in AxD astrocytes. Because the unfolded protein response in the endoplasmic reticulum (ER) can be enacted by proteasomal inhibition, I examined the immunohistochemical expression of two proteins commonly increased under conditions of ER stress. We found BIP/Grp78, an ER chaperone, increased in AxD patient astrocytes and model mice. Additionally, the CCAAT enhancer binding protein homologous protein (CHOP) was expressed by a small subset of astrocytes in the AxD mouse hippocampus, unveiling ER stress as a potential contributory factor in AxD pathology. Work in other labs has found iron in astrocytes in AxD model mice. To further elucidate mechanisms of cellular stress in AxD, I conducted an immunohistochemical analysis of iron and several regulatory proteins in AxD patients and found, by enhanced Perls' staining, Fe3+ in Rosenthal fibers and iron and ferritin accumulated in astrocytes. This finding is in marked contrast to what one sees in the normal CNS, with little staining of astrocytes, and easily detectable staining of oligodendrocytes. Finally, I examined the localization of the cell surface glycoprotein CD44, along with several related proteins, including its ligand hyaluronan. I found CD44 protein expression greatly increased in the white matter, cortex and hippocampus of AxD patients and in the hippocampus of AxD mice. Additionally, through use of a biotinylated hyaluronan binding protein, I found abnormally high levels of hyaluronan in the hippocampus of AxD mice in the same areas where increases in CD44 were found. Work elsewhere has found CD44 and hyaluronan in other disorders that affect myelination, and experiments have revealed an inhibitory effect of hyaluronan on oligodendrocyte development and myelination. The studies in this thesis contribute novel stressors to the list of those that impact astrocytes in AxD and, in particular, suggest the accumulation of iron in astrocytes as potentially important to the pathological manifestations of AxD. Additionally, my research has revealed dramatic increases in the expression of CD44 in AxD astrocytes which, in conjunction with widespread increases in hyaluronan, may be critical to understanding the mechanisms underlying the de/dysmyelination that occur in this disease.
| Identifer | oai:union.ndltd.org:columbia.edu/oai:academiccommons.columbia.edu:10.7916/D8902B0Q |
| Date | January 2013 |
| Creators | Guilfoyle, Eileen M. |
| Source Sets | Columbia University |
| Language | English |
| Detected Language | English |
| Type | Theses |
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