Abstract
BackgroundCentral to the pathogenesis of Alzheimer’s disease (AD) and many other neurodegenerative diseases is the conformational change of a normal self-protein into toxic oligomeric species and amyloid deposits. None of these disorders have an effective therapy, but immunization approaches hold great promise. We have previously shown that active immunization with a novel peptide when polymerized into a stable oligomeric conformation, pBri, induced a humoral immune response to toxic Aβ species in an AD model, APP/PS1 transgenic (Tg) mice, reducing plaque deposits. pBri is a glutaraldehyde polymerized form of the carboxyl fragment of an amyloidogenic protein, which is deposited in the brains of patients with a rare autosomal dominant disease due to a missense mutation in a stop codon, resulting in the translation of an intronic sequence, with no known sequence homology to any mammalian protein.MethodsIn the current study we tested whether pBri-peptide-based immunomodulation is effective at reducing both vascular amyloid deposits and tau-related pathology using TgSwDI mice with extensive congophilic angiopathy and 3xTg mice with tau pathology.ResultsOur results indicate that this immunomodulation approach, which produces a humoral response to proteins in a pathological conformation, is effective at reducing both Aβ and tau-related pathologies.ConclusionsThis immunomodulatory approach has the advantage of using a non-self-immunogen that is less likely to be associated with autoimmune toxicity. Furthermore we found that it is able to target all the cardinal features of AD concurrently.
Highlights
Alzheimer’s disease (AD) is the most common cause of dementia globally, affecting approximately 36 million people currently and approximately 115 million by 2050 [1]
To develop a highly successful immunotherapy for AD patients, several problems need to be overcome including: avoiding excessive cell-mediated immunity, which has been linked to autoimmune encephalitis; reducing congophilic amyloid angiopathy (CAA) deposition without inducing associated microhemorrhages and/ or vasogenic edema; reducing tau-related pathology, which is known to correlate with clinical status better than amyloid deposits, and targeting of oligomeric species, which are the most toxic [3]
In the control groups for both TgSwDI and 3xTg strains, as expected, there were no significant differences in T1 and Tf titers against Aβ40, Aβ42 and polymerized British amyloidosis (pBri) versus T0, with optical density (OD) values all being ≤0.03
Summary
Alzheimer’s disease (AD) is the most common cause of dementia globally, affecting approximately 36 million people currently and approximately 115 million by 2050 [1]. British amyloidosis (ABri) is a rare form of familial human amyloidosis associated with a missense mutation in a stop codon This mutation results in the transcription of an intronic sequence, leading to the production of a highly amyloidogenic protein with a carboxyl terminus that has no sequence homology to any other native human protein, including Aβ and tau [14,15,16]. Central to the pathogenesis of Alzheimer’s disease (AD) and many other neurodegenerative diseases is the conformational change of a normal self-protein into toxic oligomeric species and amyloid deposits None of these disorders have an effective therapy, but immunization approaches hold great promise. PBri is a glutaraldehyde polymerized form of the carboxyl fragment of an amyloidogenic protein, which is deposited in the brains of patients with a rare autosomal dominant disease due to a missense mutation in a stop codon, resulting in the translation of an intronic sequence, with no known sequence homology to any mammalian protein We have previously shown that active immunization with a novel peptide when polymerized into a stable oligomeric conformation, pBri, induced a humoral immune response to toxic Aβ species in an AD model, APP/PS1 transgenic (Tg) mice, reducing plaque deposits. pBri is a glutaraldehyde polymerized form of the carboxyl fragment of an amyloidogenic protein, which is deposited in the brains of patients with a rare autosomal dominant disease due to a missense mutation in a stop codon, resulting in the translation of an intronic sequence, with no known sequence homology to any mammalian protein
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