Abstract
Physiological non-amyloidogenic processing (NAP) of amyloid precursor holoprotein (hAPP) by α-secretases (e.g., ADAM10) extracellularly sheds neurotrophic/neuroprotective soluble (s)APPα and precludes amyloid-β peptides (Aβs) production via β-secretase amyloidogenic processing (AP). Evidence exists that Aβs interact with calcium-sensing receptors (CaSRs) in human astrocytes and neurons, driving the overrelease of toxic Aβ42/Aβ42-os (oligomers), which is completely blocked by CaSR antagonist (calcilytic) NPS 2143. Here, we investigated the mechanisms underlying NPS 2143 beneficial effects in human astrocytes. Moreover, because Alzheimer’s disease (AD) involves neuroinflammation, we examined whether NPS 2143 remained beneficial when both fibrillary (f)Aβ25–35 and a microglial cytokine mixture (CMT) were present. Thus, hAPP NAP prevailed over AP in untreated astrocytes, which extracellularly shed all synthesized sAPPα while secreting basal Aβ40/42 amounts. Conversely, fAβ25–35 alone dramatically reduced sAPPα extracellular shedding while driving Aβ42/Aβ42-os oversecretion that CMT accelerated but not increased, despite a concurring hAPP overexpression. NPS 2143 promoted hAPP and ADAM10 translocation to the plasma membrane, thereby restoring sAPPα extracellular shedding and fully suppressing any Aβ42/Aβ42-os oversecretion, but left hAPP expression unaffected. Therefore, as anti-AD therapeutics calcilytics support neuronal viability by safeguarding astrocytes neurotrophic/neuroprotective sAPPα shedding, suppressing neurons and astrocytes Aβ42/Aβ42-os build-up/secretion, and remaining effective even under AD-typical neuroinflammatory conditions.
Highlights
Physiological non-amyloidogenic processing (NAP) of amyloid precursor holoprotein by α-secretases (e.g., ADAM10) extracellularly sheds neurotrophic/neuroprotective soluble (s)APPα and precludes amyloid-β peptides (Aβs) production via β-secretase amyloidogenic processing (AP)
Given the potential value for Alzheimer’s disease (AD) therapy, in this work, we explored for the first time the mechanisms underlying the beneficial effects of NPS 2143 in human astrocytes, the effects of AβCaSR signalling on the NAP of hAPP and the modulation of such effects by a calcilytic
Co-treatment with cytokine mixture (CMT) hastened the secretion of endogenous Aβ42/Aβ42-os, which peaked at 48 h (Fig. 1a)
Summary
Physiological non-amyloidogenic processing (NAP) of amyloid precursor holoprotein (hAPP) by α-secretases (e.g., ADAM10) extracellularly sheds neurotrophic/neuroprotective soluble (s)APPα and precludes amyloid-β peptides (Aβs) production via β-secretase amyloidogenic processing (AP). The typical markers of AD are senile plaques, i.e., accumulations of amyloid-β peptides (Aβs) in the neuropil; neurofibrillary tangles (NFTs), i.e., insoluble clusters of hyperphosphorylated Tau proteins inside neurons; the loss of synaptic contacts; neurotoxicity; increased cell death in neurons and oligodendrocytes; activated astrocytes and microglia; chronic neuroinflammation; cerebrovascular damage; and blood-brain barrier dysfunction[2,3,4]. These markers are present in extended cortical areas up to fifteen years before the onset of any memory or cognition decline[2, 5, 6]. Such Aβs devastatingly spread from the hippocampus to a wide range of upper cortical areas[22,23,24]
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