Aspartylglucosaminuria (AGU) is a neurodegenerative lysosomal storage disease that is caused by mutations in the gene encoding for a soluble hydrolase, aspartylglucosaminidase (AGA). In this study, we have used our recently developed mouse model for AGU and analyzed processing, intracellular localization, and endocytosis of recombinant AGA in telencephalic AGU mouse neurons in vitro . The processing steps of AGA were found to be similar to the peripheral cells, but both the accumulation of the inactive precursor molecule and delayed lysosomal processing of the enzyme were detected. AGA was distributed to the cell soma and neuronal processes but was not found in the nerve terminals. Endocytotic capability of cultured telencephalic neurons was comparable to that of fibroblasts, and endocytosis of AGA was blocked by free mannose-6-phosphate (M6P), indicating that uptake of the enzyme was mediated by M6P receptors (M6PRs). Uptake of extracellular AGA was also studied in the tumor-derived cell lines rat pheochromocytoma (PC12) and mouse neuroblastoma cells (N18), which both endocytosed AGA poorly as compared with cultured primary neurons. Expression of cation-independent M6PRs (CI-M6PRs) in different cell lines correlated well with the endocytotic capability of these cells. Although a punctate expression pattern of CI-M6PRs was found in fibroblasts and cultured primary neurons, the expression was beyond the detection limit in PC12 and N18 cells. This indicates that PC12 and N18 are not feasible cell lines to describe neuronal uptake of mannose-6-phosphate-tagged proteins. This in vitro data will form an important basis for the brain-targeted therapy of AGU.
As a possible diagnostic marker for Alzheimer's disease (AD), we investigated beta-amyloid protein (beta/A4) immunoreactivity in skin. Furthermore, we studied the presence of beta-amyloid precursor protein 695 immunoreactivity in skin.Lifetime skin biopsy specimens were stained for beta/A4 and beta-amyloid precursor protein 695. The follow-up period was 12 months. We determined the correlation between beta/A4 immunoreactivity in skin and brain in patients with a neuropathologic diagnosis.All patients with dementia were hospitalized; most of them had moderate to severe dementia. Aged nondemented controls were residents of a nursing home. The Down's syndrome (DS) group included both hospitalized and ambulatory patients. Young nondemented controls were medical students or staff members who volunteered for the study.The study included a total of 111 subjects. Thirty-five patients had probable AD, nine had possible AD, 15 had multi-infarct dementia, one had idiopathic Parkinson's disease, and one had Parkinson's disease and possible AD. There were also 19 elderly nondemented controls, 23 patients with DS, and eight young nondemented controls.Immunohistochemical detection of beta/A4 in skin and correlation to the diagnosis of AD.Immunopositivity for beta/A4 antibody was present in and around the endothelium of dermal blood vessels in a proportion of patients with AD and multi-infarct dementia as well as elderly controls. The patients with sporadic AD displayed beta/A4 immunoreactivity significantly more frequently than did patients with familial AD, patients with multi-infarct dementia, and controls. The beta/A4 immunopositivity in skin was rare in the patients with DS and not present in young controls. Instead, 48% of patients with DS but none of other groups had beta-amyloid precursor protein 695 immunoreactivity in skin. Only four (31%) of 13 patients with neuropathologically confirmed AD had shown endothelial beta/A4 immunopositivity in skin biopsy specimens while alive.Our results do not support beta/A4 as a diagnostic marker for AD.
Mutations in the CLN-1 and CLN-5 genes underlie the infantile, and Finnish variant of the late-infantile, neuronal ceroid lipofuscinoses, respectively. These disorders are characterized by a massive neuronal death early in childhood. We have studied mRNA and protein expression of CLN-1 and CLN-5 in embryonic human brains. The spatial and temporal distributions of CLN-1 and CLN-5 were similar in the embryonic human brain. Both genes are expressed at the beginning of cortical neurogenesis, and this expression increases as cortical development proceeds. In the developing cortical plate, expression is found in postmitotic migrating neuroblasts and neuroblasts that have completed migration. Expression was intense also in cells of the thalamus as well as in the future Purkinje cell layer of the cerebellum. These findings indicate that expression of CLN-1 and CLN-5 may be significant for development of a wide range of maturating neurons.
Gelsolin-related amyloidosis or familial amyloidosis, Finnish type (FAF) (OMIM No105120) is a hereditary amyloid disease caused by a mutation in a precursor protein for amyloid (gelsolin) and characterized by corneal dystrophy and polyneuropathy. In vitro expression of the FAF-mutant (Asp187 --> Asn/Tyr) secretory gelsolin in COS cells leads to generation of an aberrant polypeptide presumably representing the precursor for tissue amyloid. Here, we provide evidence that this abnormal processing results from defective initial folding of the secreted FAF gelsolin due to the lack of the Cys188-Cys201 disulfide bond, normally formed next to the FAF mutation site. We compared cells of different tissue origin and discovered a dramatic difference between the amount of cleavage of FAF gelsolin to the amyloid precursor in neuronal and non-neuronal cells. More than half of the mutant gelsolin was cleaved in PC12 and in vitro differentiated human neuronal progenitor cells. In contrast, human fibroblasts and Schwannoma cell cultures showed only a limited capacity to cleave FAF gelsolin, although the cleavage mechanism per se seems to be similar in the various cell types. The present findings of processing and distribution of secreted FAF gelsolin in the neuronal cells emphasize the role of neurons in the tissue pathogenesis of this amyloid polyneuropathy.
WE measured CSF acetylcholinesterase (AChE) activity in 57 Alzheimer's disease (AD) patients with different apolipoprotein E (apoE) genotypes at the early stage of the disease, and in 11 non-demented controls. The AChE activities of the whole AD group did not differ from those of controls. However, analysis of variance over the AD subgroups with two, one or no ε4 alleles and controls showed significant differences (p < 0.0001); the AD patients with two ε4 alleles had higher AChE activities than controls and AD patients with one or no ε4 and also the AD patients carrying one ε4 allele had higher AChE activities than the AD patients without the ε4 allele. The study suggests that cholinergic metabolism is altered in proportion to the number of apoE ε4 alleles. The different degree of AChE activity in relation to the number of ε4 alleles might have an impact on AD patients' responses to cholinesterase inhibitors.
