Nilson Nunes-Tavares scite author profile

Background: Cholinergic dysfunction is an early feature of Alzheimer disease (AD). Results: Soluble oligomers of the amyloid-␤ peptide (A␤) bind to cholinergic neurons and inhibit choline acetyltransferase (ChAT) activity before any cell death or lesion. Conclusion: ChAT inhibition might impair acetylcholine production and cholinergic function in AD brains. Significance: This novel effect of A␤ oligomers may be relevant in early stage AD pathology.

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A novel crosslinking protocol stabilizes amyloid β oligomers capable of inducing Alzheimer's‐associated pathologies

Cline

Das

Bicca

et al. 2019

Journal of Neurochemistry

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Amyloid β oligomers (AβOs) accumulate early in Alzheimer's disease (AD) and experimentally cause memory dysfunction and the major pathologies associated with AD, for example, tau abnormalities, synapse loss, oxidative damage, and cognitive dysfunction. In order to develop the most effective AβO‐targeting diagnostics and therapeutics, the AβO structures contributing to AD‐associated toxicity must be elucidated. Here, we investigate the structural properties and pathogenic relevance of AβOs stabilized by the bifunctional crosslinker 1,5‐difluoro‐2,4‐dinitrobenzene (DFDNB). We find that DFDNB stabilizes synthetic Aβ in a soluble oligomeric conformation. With DFDNB, solutions of Aβ that would otherwise convert to large aggregates instead yield solutions of stable AβOs, predominantly in the 50–300 kDa range, that are maintained for at least 12 days at 37°C. Structures were determined by biochemical and native top–down mass spectrometry analyses. Assayed in neuronal cultures and i.c.v.‐injected mice, the DFDNB‐stabilized AβOs were found to induce tau hyperphosphorylation, inhibit choline acetyltransferase, and provoke neuroinflammation. Most interestingly, DFDNB crosslinking was found to stabilize an AβO conformation particularly potent in inducing memory dysfunction in mice. Taken together, these data support the utility of DFDNB crosslinking as a tool for stabilizing pathogenic AβOs in structure‐function studies.

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Protein CutA Undergoes an Unusual Transfer into the Secretory Pathway and Affects the Folding, Oligomerization, and Secretion of Acetylcholinesterase

Liang

Nunes-Tavares

Xie

et al. 2009

Journal of Biological Chemistry

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The mammalian protein CutA was first discovered in a search for the membrane anchor of mammalian brain acetylcholinesterase (AChE). It was co-purified with AChE, but it is distinct from the real transmembrane anchor protein, PRiMA. CutA is a ubiquitous trimeric protein, homologous to the bacterial CutA1 protein that belongs to an operon involved in resistance to divalent ions ("copper tolerance A"). The function of this protein in plants and animals is unknown, and several hypotheses concerning its subcellular localization have been proposed. We analyzed the expression and the subcellular localization of mouse CutA variants, starting at three in-frame ATG codons, in transfected COS cells. We show that CutA produces 20-kDa (H) and 15-kDa (L) components. The H component is transferred into the secretory pathway and secreted, without cleavage of a signal peptide, whereas the L component is mostly cytosolic. We show that expression of the longer CutA variant reduces the level of AChE, that this effect depends on the AChE C-terminal peptides, and probably results from misfolding. Surprisingly, CutA increased the secretion of a mutant possessing a KDEL motif at its C terminus; it also increased the formation of AChE homotetramers. We found no evidence for a direct interaction between CutA and AChE. The longer CutA variant seems to affect the processing and trafficking of secretory proteins, whereas the shorter one may have a distinct function in the cytoplasm.

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Inhibition of acetylcholinesterase from Electrophorus electricus (L.) by tricyclic antidepressants

Nunes-Tavares

Matta

Silva

et al. 2002

The International Journal of Biochemistry & Cell Biology

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