Potential of molecular chaperones for treating Alzheimer’s disease

Gefei Chen,Jan Johansson

Alzheimer’s disease (AD) is the most prevalent form of dementia,i.e.,progressive memory loss and profound cognitive dysfunction,resulting in a considerable societal burden.At the neuropathological level,the brains of ΑD patients exhibit amyloid-β (Αβ) plaques,neurofibrillary tangles,and neuroinflammation (Sala Frigerio and De Strooper,2016).The growing number of individuals affected with AD underscores the pressing need for the development of effective treatments,and a cure remains elusive.The pathogenesis of AD involves intricate molecular and cellular mechanisms that lead to progressive neurodegeneration and cognitive decline.A central tenet of AD pathogenesis is the amyloid cascade hypothesis,which posits that the accumulation of Αβ peptides plays a pivotal role in disease progression.Αβ derives from the amyloid precursor protein (ΑPP) by BΑCE1 (β-secretase)and γ-secretase cleavages,and aggregates into plaques that eventually disrupt neuronal function.Concurrently,abnormal phosphorylation of the tau protein leads to the formation of neurofibrillary tangles,contributing to neuronal degeneration.Neuroinflammation,oxidative stress,mitochondrial dysfunction,and synaptic impairment further compound the pathology(Sala Frigerio and De Strooper,2016).The intricate interplay of these phenomena underscores the challenges in treating ΑD,necessitating innovative therapeutic approaches to halt or slow disease progression effectively.Recently,monoclonal antibody drugs,like Αducanumab,Lecanemab,and Donanemab,have shown the ability to decelerate memory and cognitive decline in phase III clinical trials of early-stage ΑD (Boxer and Sperling,2023).Αducanumab is designed to bind Αβ aggregates in both the oligomeric and fibrillar states rather than amyloid monomers,while Lecanemab has been proposed to target so called Αβ protofibrils.Donanemab is directed against N-terminally modified form of Αβ.These clinical trials collectively suggest that the approach to target Αβ represents an effective strategy for treating AD,particularly in its early stages.

While antibody drugs have gained significant attention for their effects in mitigating memory and cognitive deterioration in early-stage AD,several crucial aspects warrant consideration,including (1) Efficacy and side effects: While the antibodies do play a role in slowing the progression of ΑD,the magnitude of their efficacy may vary,and the benefits need to be weighed against the probability of side effects (Boxer and Sperling,2023).This underscores the importance of a thorough assessment of both the benefits and potential drawbacks of these drugs.(2) Bloodbrain barrier permeability: The development of compounds for AD faces a notable failure rate,with many tested compounds,particularly antibodies,exhibiting poor permeability across the blood-brain barrier.This limitation poses an obstacle in treating central nervous system disorders and emphasizes the need for innovative approaches to enhance drug delivery.(3) Latestage AD treatment: AD is typically diagnosed in its later stages,characterized by observable cognitive decline and memory impairment.It remains unclear whether drugs effective in early-stage AD exhibit the same efficacy in later stages.This highlights the necessity for treatment strategies that take into account the evolving nature of the disease.(4) Multifactorial nature of ΑD: Αβ is recognized as a significant contributor to AD,but it is probably not the sole driving force,and factors like tau pathology,neuro-inflammation,and oxidative stress also play integral roles.Thus,there is a growing acknowledgment of the need to develop interventions that comprehensively target the multifactorial aspects of ΑD.

Molecular chaperones play a crucial role in preserving cellular protein homeostasis(proteostasis).ATP-independent molecular chaperones,often referred to as “holdases”,maintain (partially) unfolded client proteins in a folding-competent state without necessarily refolding them,leaving the task of refolding or degradation to other cellular systems.Experimental data suggest that these chaperones,including small heat shock proteins (sHsps),can prevent or resolve protein aggregation also in neurodegenerative diseases including AD.For instance,Hsp27 (HspB1) impedes the formation of tau fibrils by engaging in weak interactions with early species during the aggregation process,and mitigates the toxicity of Αβ oligomers by sequestering them and transforming them into larger,non-toxic aggregates (Wentink et al.,2019).αB-crystallin (HspB5) binds to both wildtype Αβ42fibrils and fibrils formed from the Αβ42E22G(Arctic) mutant and subsequently inhibits amyloid fibril formation (Wentink et al.,2019).Further,Nuclebindin-1 (NUCB1),identified as a novel chaperone-like amyloid-binding protein,demonstrates inhibitory effects on the aggregation of islet amyloid polypeptide (IAPP) linked to type 2 diabetes,α-synuclein associated with Parkinson’s disease,transthyretin V30M mutant related to familial amyloid polyneuropathy,and Αβ42(Bonito-Oliva et al.,2017).In contrast,ATPdependent molecular chaperones assist substrates in adopting their native conformation (“foldases”)or prepare them for degradation.DNAJB6,a member of the Hsp40 heat shock protein family,demonstrates a high efficiency in inhibiting Αβ42amyloid formation (Wentink et al.,2019).The extracellular secretion of Hsp70 demonstrates protection against Αβ42-induced toxicity,effectively mitigating neurotoxicity in adult eyes,reducing cell death,preserving the structural integrity of adult neurons,alleviating locomotor dysfunction,and extending lifespan.Additionally,engineered Hsp70 chaperones prove effective in preventing Αβ42-induced memory impairments in aDrosophilamodel (Wentink et al.,2019).While the majority of information about molecular chaperones centers around sHSPs primarily located intracellularly,the discovery of extracellular proteins with ATPindependent molecular chaperone functions likely reflects the need for chaperoning outside the cell.Clusterin,a major extracellular chaperone(Humphreys et al.,1999),has been demonstrated to inhibit Αβ42aggregation by disrupting the nucleation process rather than affecting the fibril elongation rate.In rat brains,microinjection of Αβ42oligomers,pre-incubated for 1 hour with extracellular chaperones such as clusterin or α2-macroglobulin,prevents Αβ42-induced learning and memory impairments,reduces Αβ42-induced gliosis and neuronal degeneration,and suppresses oligomer cytotoxicity.Αdditionally,an intracellular form of clusterin has been identified as a tau-interacting protein (Foster et al.,2019).Furthermore,intraventricular infusion of clusterin has been shown to ameliorate cognition and reduce pathology in the Tg6799 model of AD(Qi et al.,2018),while peripheral administration of human recombinant clusterin was able to modulate brain Αβ levels in ΑPP23 mice (de Retana et al.,2019).Interestingly,disrupted proteostasis and persistent unfolded protein response activity are identified in AD,and notably,chemical chaperone treatment successfully restores proteostasis in a mouse model of AD,leading to improved cognition and reduced pathology (Hafycz et al.,2023).While these findings underscore the potential of chaperones for the multi-targeted treatment of AD,challenges may exist in their ability to cross the blood-brain barrier.Further,as Αβ accumulates extracellularly in senile plaques and tau accumulates intracellularly in tangles in AD brain,further research is needed to optimize therapeutic strategies for molecular chaperones in AD.

In contrast to classical molecular chaperones,the BRICHOS domain,consisting of approximately 100 amino acid residues,stands out as an antiamyloid molecular chaperone.BRICHOS is present in proproteins encompassing an amyloidforming region,in which the BRICHOS domain is thought to prevent the amyloidogenic region from forming aggregates (Leppert et al.,2023).The term “BRICHOS”is derived from the initially identified proproteins containing this domain,namely Bri2,chondromodulin-1,and prosurfactant protein C.Under physiological conditions,BRICHOS supposedly facilitates the proper folding of the amyloid-prone region within the respective proprotein,and is then proteolytically released (Sánchez-Pulido et al.,2002;Chen et al.,2022).Recent research has shown that the recombinant BRICHOS domain is a versatile antiamyloid molecular chaperone with a broad substrate spectrum,encompassing also “alien”client peptides (i.e.,not parts of the BRICHOS proproteins) associated with various human amyloid diseases as well as bacterial functional amyloid-forming peptides and proteins,including ΑD-relevant Αβ42and Αβ40,as well as Huntington’s disease-associated huntingtin peptide,Parkinson’s disease-linked α-synuclein,aortic amyloid-forming peptide medin,functional amyloid-forming protein C,and thede novo-designed peptide β17(Figure 1).For instance,BRICHOS binds to amyloid fibrils of Αβ42and IAPP,effectively reduce their cellular toxicity and interact with the smallest emerging toxic Αβ oligomers.BRICHOS also binds to amyloid fibrils associated with Huntington’s disease and α-synuclein linked to Parkinson’s disease.Intriguingly,BRICHOS efficiently reduces,and can rescue,Αβ neurotoxicity in mouse hippocampal slice preparations (Leppert et al.,2023).BRICHOS passes the blood-brain barrier in wild-type mice and AD mouse models,allowing intravenous administration (Leppert et al.,2023).The preventive and therapeutic effects of BRICHOS against amyloid fibril formation,toxicity,and AD have undergone rigorous testing (Figure 1;Leppert et al.,2023).In aDrosophila melanogasterfly model expressing Αβ42,brain-expressed BRICHOS gave a reduction in Αβ42deposition,improved lifespan,enhanced locomotor activity,and rescued pathological eye phenotypes.Co-expression of BRICHOS resulted in a notable shift in intracellular distribution of Αβ42in theDrosophilamushroom body.In an AD mouse model overexpressing mutant APP and presenilin 1,coexpression of BRICHOS led to reduced Αβ levels and aggregation without impacting APP processing.Mice coexpressing BRICHOS exhibited improved memory and reduced neuroinflammation compared to ΑβPP/presenilin 1 control animals that overexpressed green fluorescent protein.Recently,in an APP knockin (APPNL-F) AD mouse model,which harbors the Swedish (KM670/671NL) and Beyreuther/Iberian (I716F) mutations and develops Αβ plaque pathology,astrogliosis,and microgliosis starting from an age of about 9–12 months,repeated intravenous BRICHOS treatment from age of 19 months for 2 months,reduced plaque burden and gliosis in the cortex.With a similar administration approach,BRICHOS was applied to a 3-month APPNL-G-Fknockin AD mouse model,which in addition carries the Αrctic mutation (E693G)mutation and develops ΑD-like pathology features from an age of about 2–4 months because of the more aggressive fibril formation of Αrctic Αβ.The treatment with BRICHOS improved recognition and working memory reduced Αβ plaque deposition,and decreased activation of astrocytes and microglia (Manchanda et al.,2023).Recombinant human BRICHOS has also been administrated to 10 months old APPNL-G-Fknockin mice,i.e.,at a stage where AD pathology is established since long,which led to reduced Αβ amyloid burden,mitigated astro-and microgliosis,and altered ΑDrelevant gene expression.Taken together,the anti-amyloid chaperone domain BRICHOS emerges as a promising candidate for multi-targeted treatment of AD,which warrants further investigation through clinical trials.

Figure 1｜Activities and applications of the anti-amyloid chaperone domain BRICHOS.

In summary,the two primary hallmarks of AD are senile plaques and neurofibrillary tangles,stemming from the aggregation of Αβ and tau proteins,respectively.While monoclonal antibody drugs were specifically designed to target Αβ,molecular chaperones,particularly the anti-amyloid chaperone domain BRICHOS,exhibit abilities to interfere with various amyloidforming peptides and proteins,including Αβ and tau.Notably,BRICHOS has demonstrated superior efficacy in preventing the formation of toxic Αβ oligomers compared to the monoclonal antibody aducanumab and mechainism underlying antibodies and molecular chaperone (-like)proteins discussed in (Abelein and Johansson,2023).Further research efforts are crucial to optimize approaches for effective ΑD treatment.

This work was supported by grants from the Alzheimer’s Association Research Grant(to GC),Olle Engkvists Stiftelse(to GC),the Petrus and Augusta Hedlunds Stiftelse(to GC),?ke Wibergs stiftelse(to GC),the Swedish Alzheimer foundation(to GC),the ?hlén Stiftelsens(to GC),Karolinska Institutet Research Foundation Grant(to GC),the Stiftelsen f?r Gamla Tj?narinnor(to GC),the Stiftelsen Sigurd och Elsa Goljes Minne(to GC),the Loo and Hans Osterman Foundation(to GC),Geriatric Diseases Foundation at Karolinska Institutet(to GC),the Gun and Bertil Stohne’s Foundation(to GC),the Magnus Bergvall Foundation(to GC).

Gefei Chen*,Jan Johansson

Department of Biosciences and Nutrition,Karolinska Institutet,Huddinge,Sweden (Chen G,Johansson J)

Department of Cell and Molecular Biology,Uppsala University,Uppsala,Sweden (Chen G)

*Correspondence to:Gefei Chen,PhD,gefei.chen@ki.se.

https://orcid.org/0000-0002-5543-5963(Gefei Chen)

Date of submission:November 24,2023

Date of decision:December 26,2023

Date of acceptance:January 9,2024

Date of web publication:March 8,2024

https://doi.org/10.4103/NRR.NRR-D-23-01927

How to cite this article:Chen G,Johansson J(2024)Potential of molecular chaperones for treating Alzheimer’s disease.Neural Regen Res 19(11):2343-2344.

Open access statement:This is an open access journal,and articles are distributed under the terms of the Creative Commons AttributionNonCommercial-ShareAlike 4.0 License,which allows others to remix,tweak,and build upon the work non-commercially,as long as appropriate credit is given and the new creations are licensed under the identical terms.