Showing papers by "Laura Colombo published in 2018"

Alpha-synuclein oligomers impair memory through glial cell activation and via Toll-like receptor 2.

Abstract: Alpha-synuclein oligomers (α-synOs) are emerging as crucial factors in the pathogenesis of synucleinopathies. Although the connection between neuroinflammation and α-syn still remains elusive, increasing evidence suggests that extracellular moieties activate glial cells leading to neuronal damage. Using an acute mouse model, we explored whether α-synOs induce memory impairment in association to neuroinflammation, addressing Toll-like receptors 2 and 4 (TLR2 and TLR4) involvement. We found that α-synOs abolished mouse memory establishment in association to hippocampal glial activation. On brain slices α-synOs inhibited long-term potentiation. Indomethacin and Ibuprofen prevented the α-synOs-mediated detrimental actions. Furthermore, while the TLR2 functional inhibitor antibody prevented the memory deficit, oligomers induced memory deficits in the TLR4 knockout mice. In conclusion, solely α-synOs induce memory impairment likely inhibiting synaptic plasticity. α-synOs lead to hippocampal gliosis that is involved in memory impairment. Moreover, while the oligomer-mediated detrimental actions are TLR2 dependent, the involvement of TLR4 was ruled out.

Molecular subtypes of Alzheimer’s disease

Abstract: Protein misfolding and aggregation is a central feature of several neurodegenerative disorders including Alzheimer’s disease (AD), in which assemblies of amyloid β (Aβ) peptides accumulate in the brain in the form of parenchymal and/or vascular amyloid. A widely accepted concept is that AD is characterized by distinct clinical and neuropathological phenotypes. Recent studies revealed that Aβ assemblies might have structural differences among AD brains and that such pleomorphic assemblies can correlate with distinct disease phenotypes. We found that in both sporadic and inherited forms of AD, amyloid aggregates differ in the biochemical composition of Aβ species. These differences affect the physicochemical properties of Aβ assemblies including aggregation kinetics, resistance to degradation by proteases and seeding ability. Aβ-amyloidosis can be induced and propagated in animal models by inoculation of brain extracts containing aggregated Aβ. We found that brain homogenates from AD patients with different molecular profiles of Aβ are able to induce distinct patterns of Aβ-amyloidosis when injected into mice. Overall these data suggest that the assembly of mixtures of Aβ peptides into different Aβ seeds leads to the formation of distinct subtypes of amyloid having distinctive physicochemical and biological properties which result in the generation of distinct AD molecular subgroups.

In Situ Tissue Labeling of Cerebral Amyloid Using HIV-Related Tat Peptide.

Abstract: Delivering peptide-based drugs to the brain is a major challenge because of the existence of the blood-brain barrier (BBB). To overcome this problem, cell-penetrating peptides derived from proteins that are able to cross biological membranes have been used as cell-permeable and brain-penetrant compounds. An example is the transactivator of transcription protein transduction domain (Tat) of the human immunodeficiency virus. The basic domain of Tat is formed of arginine and lysine amino acid residues. Tat has been used as brain-penetrant carrier also in therapies for Alzheimer disease (AD), the most common form of dementia characterized by extracellular cerebral deposits of amyloid made up of Aβ peptide. The aim of our study was to assess whether Tat bind to amyloid deposits of AD and other amyloidoses. An in situ labeling using biotinylated Tat 48-57 peptide was employed in the brain tissue with amyloid deposits made up of Aβ (patients with AD and transgenic AD mice), of prion protein (patients with Gerstmann-Straussler-Scheinker disease), and other amyloidosis, processed by different fixations and pretreatments of histological sections. Our results showed that Tat peptide binds amyloid deposits made up of Aβ, PrP, and immunoglobulin lambda chains in the brain and other tissues processed by alcoholic fixatives but not in formalin-fixed tissue. The fact that biotinylated Tat peptide stains amyloid of different biochemical composition and the specific charge characteristics of the molecules suggests that Tat may bind to heparan sulfate glicosaminoglicans, that are present in amyloid deposits. Inhibition of the binding by Tat pre-incubation with protamine reinforces this hypothesis. Binding of Tat to amyloid deposits should be kept in mind in interpreting the results of studies employing this molecule as brain-penetrating compound for the treatment of cerebral amyloidoses. Our results also suggest that Tat may be helpful for the analysis of the mechanisms of amyloidogenesis, and in particular, the interactions between specific amyloid peptides and glicosaminoglicans.