Wenxue Li

Microvascular Changes in the Brain in Covid-19 High-resolution MRI and histopathological study of the brains of patients who had died from Covid-19 showed punctate hyperintensities and punctate or ...

Abnormal biology of alpha-synuclein (alpha-Syn) is directly implicated in the pathogenesis of Parkinson's disease and other alpha-synucleinopathies. Herein, we demonstrate that C-terminally truncated alpha-Syn (alpha-SynDeltaC), enriched in the pathological alpha-Syn aggregates, is normally generated from full-length alpha-Syn independent of alpha-Syn aggregation in brains and in cultured cells. The accumulation of alpha-SynDeltaC is enhanced in neuronal cells as compared with nonneuronal cells. Significantly, the expression of familial Parkinson's disease-linked mutant alpha-Syn is associated with the enhanced cellular accumulation of alpha-SynDeltaC. Moreover, substoichiometric amounts of alpha-SynDeltaC enhance the in vitro aggregation of the more abundant full-length alpha-Syn. Finally, cases of alpha-synucleinopathy exhibit increases in the total soluble alpha-Syn and a higher proportion of soluble alpha-SynDeltaC, a condition favoring the aggregation of alpha-Syn. Collectively, our results indicate that the biology behind the generation and accumulation of alpha-SynDeltaC is likely to have relevance for the initiation and the progression of alpha-Syn aggregation in vivo.

We examined the potential relationship between aging and alpha-synuclein (alpha-Syn) metabolism, both of which are implicated in the pathogenesis of Parkinson's disease (PD) and other alpha-synucleinopathies. During aging,alpha-Syn and beta-Syn mRNA expression in brain decreases, but the protein levels are maintained at high levels. Significantly, the alpha-Syn protein level increases with aging in human substantia nigra. Pulse-chase analyses of alpha-Syn half-lives in neurons and neuronal cell lines indicate that, in mature neurons, the expression of alpha-Syn is regulated by the post-translational stabilization of alpha-Syn protein. Moreover, A53T mutant human alpha-Syn exhibits increased stability in neuronal cell lines, leading to higher levels of the mutant protein in cells and transgenic mice. Inhibitor studies suggest that the proteasomal and lysosomal systems may not be responsible for the differential stabilization or metabolism of alpha-Syn protein in neuronal cells. Because increased stabilization of alpha-Syn protein is associated with increased protein levels and accumulation of pathogenic protein modifications, such as oxidative damage, the stabilization of alpha-Syn with aging may be a significant factor in the pathogenesis of alpha-synucleinopathies.

Peroxiredoxin Q (Prx Q) is one out of 10 peroxiredoxins encoded in the genome of Arabidopsis thaliana, and one out of four that are targeted to plastids. Peroxiredoxin Q functions as a monomeric protein and represents about 0.3% of chloroplast proteins. It attaches to the thylakoid membrane and is detected in preparations enriched in photosystem II complexes. Peroxiredoxin Q decomposes peroxides using thioredoxin as an electron donor with a substrate preference of H(2)O(2) > cumene hydroperoxide >> butyl hydroperoxide >> linoleoyl hydroperoxide and insignificant affinity towards complex phospholipid hydroperoxide. Plants with decreased levels of Prx Q did not have an apparently different phenotype from wildtype at the plant level. However, similar to antisense 2-cysteine (2-Cys) Prx plants [Baier, M. et al. (2000)Plant Physiol., 124, 823-832], Prx Q-deficient plants had a decreased sensitivity to oxidants in a leaf slice test as indicated by chlorophyll a fluorescence measurements. Increased fluorescence ratios of photosystem II to I at 77 K and modified transcript levels of plastid- and nuclear-encoded proteins show that regulatory mechanisms are at work to compensate for the lack of Prx Q. Apparently Prx Q attaches to photosystem II and has a specific function distinct from 2-Cys peroxiredoxin in protecting photosynthesis. Its absence causes metabolic changes that are sensed and trigger appropriate compensatory responses.