Selective neutralization of APP-C99 with monoclonal antibodies reduces the production of Alzheimer's Aβ peptides

The toxic amyloid-β (Aβ) peptides involved in Alzheimer's disease (AD) are produced after processing of the amyloid precursor protein-C-terminal fragment APP-C99 by γ-secretase. Thus, major therapeutic efforts have been focused on inhibiting the activity of this enzyme. However, preclinical and clinical trials testing γ-secretase inhibitors revealed adverse side effects most likely attributed to impaired processing of the Notch-1 receptor, a γ-secretase substrate critically involved in cell fate decisions. Here we report an innovative approach to selectively target the γ-secretase-mediated processing of APP-C99 with monoclonal antibodies neutralizing this substrate. Generated by immunizing mice with natively folded APP-C99, these antibodies bound N- or C-terminal accessible epitopes of this substrate, and decorated extracellular amyloid deposits in AD brain tissues. In cell-based assays, the same antibodies impaired APP-C99 processing by γ-secretase, and reduced Aβ production. Furthermore, they significantly decreased brain Aβ levels in the APPPS1 mouse model of AD after intracerebroventricular injection. Together, our findings support APP-C99 substrate-targeting antibodies as new immunotherapeutic and Notch-sparing agents to lower the levels of Aβ peptides implicated in AD.

Nucleation Dependent Polymerization of Amyloid-ß (Aß) as an Important Determinant of Aß Amyloid Formation and Neurotoxicity

Mohammad Asad Jan Qureshi

Aggregation and fibril formation of amyloid-β (Aβ) peptides play a pivotal role in the pathogenesis of Alzheimer's disease (AD). Aβ peptides, principally comprising of 40 or 42 amino acid residues (Aβ40 and Aβ42), are produced by proteolytic processing of the amyloid precursor protein by β and γ-secretase activity. A vast number of academic and biomedical industry projects are devoted to the discovery and development of therapeutic agents which inhibit the process of Aβ aggregation, and associated neurotoxicity, as potential disease modifying therapies for AD. Despite decades of research, the mechanism of Aβ neurotoxicity leading to development of AD and the identity of toxic Aβ species remain debatable. Nevertheless, independent lines of evidence implicate Aβ oligomers, which are precursors to fibrils, as putative toxic species and promising therapeutic targets. Aβ oligomers are characterized by heterogeneity in size and morphology distribution and have been shown to alter normal neuronal physiology in a manner that implicates their causal association with AD pathogenesis. The primary objective of this thesis work was to elucidate the structural determinants of Aβ neurotoxicity, the relationship of fibril formation process with neurotoxicity and identify neurotoxic Aβ species. Towards achieving these goals, we first developed and optimized reproducible protocols for generating various Aβ species, including monomers, protofibrils and fibrils, and established methods for detailed characterization of their structural properties. To better understand the relationship between Aβ aggregation and neurotoxicity, cell culture assays using primary neurons and neuronal cell lines were developed and used to assess the toxicity of various Aβ aggregates. Using these assays and biochemical tools, we sought to answer some of the key outstanding questions in the field concerning the role of Aβ amyloid formation process in neurodegeneration in AD. What is the nature of neurotoxic Aβ species and how does the process of its formation relate to neurodegeneration in AD? The identification of toxic Aβ species and/or process of its formation is crucial for understanding the mechanism(s) of Aβ neurotoxicity in AD, and development of effective diagnostic tools and therapeutic interventions. To achieve this, we successfully isolated protofibrils of distinct sizes and morphology distribution and compared their fibrillization and neurotoxicity to monomeric and fibrillar forms of Aβ. The results from our studies implicate an ongoing Aβ polymerization process, rather than distinct Aβ aggregate states (fibrillar or non-fibrillar), as primary determinant of Aβ neurotoxicity. We showed that crude Aβ42 preparations containing mixtures of monomers and heterogeneous oligomers were significantly more toxic than purified Aβ42 protofibril preparations. Subfractionation of protofibril preparations, to separate different protofibril species, resulted in further attenuation of their toxicity. The slow fibrillization of purified and subfractionated Aβ42 protofibrils was strongly linked to their diminished toxicity; thus, demonstrating that Aβ42 toxicity is not necessarily linked to specific prefibrillar aggregate(s), but rather to the ability of these species to grow and undergo fibril formation in presence of monomeric Aβ42. Consistent with this hypothesis, reintroduction of monomeric Aβ42 into these fractions restored amyloid formation and enhanced their toxicity to comparable levels as observed for the crude preparations. Furthermore, selective removal of monomeric Aβ42 from these preparations, using insulin degrading enzyme (IDE), reversed the toxicity of Aβ42 protofibrils. Together, these findings provide strong evidence thatAβ toxicity is linked to an ongoing Aβ polymerization process and is greatly reduced when the polymerization process is slowed down by selective removal/degradation of monomers. What is the molecular basis underlying the protective role of Aβ40 against Aβ42 amyloid formation and neurotoxicity in AD? The ratio of Aβ40/Aβ42 has been shown to be a critical determinant of neurodegeneration and the distribution of Aβ amyloid pathology in brain (parenchyma vs. vasculature) in AD. To investigate the molecular basis underlying the pathologic consequences associated with alterations in the ratio of Aβ40/Aβ42, we assessed fibrillization in the mixtures of different species (monomers, protofibrils and fibrils) of the two peptides at wide range of ratios and concentrations. We showed that monomeric Aβ40 alters the kinetic stability, solubility, and morphological properties of Aβ42 aggregates and prevents their conversion into mature fibrils.Aβ40, at approximately equimolar ratios (Aβ40/Aβ42∼ 0.5-1), inhibits (>50%) fibril formation by monomeric Aβ42, whereas inhibition of protofibrillar Aβ42 fibrillogenesis is achieved at lower, substoichiometric ratios (Aβ40/Aβ42 ∼ 0.1). Additionally, we demonstrated that monomeric Aβ42 and Aβ40 are constantly recycled and compete for binding to the ends of protofibrillar and fibrillar Aβ aggregates. Whereas the fibrillogenesis of both monomeric species can be seeded by fibrils composed of either peptide, Aβ42 protofibrils selectively seed the fibrillogenesis of monomeric Aβ42 but not monomeric Aβ40. Finally, we also showed that the amyloidogenic propensities of different individual and mixed Aβ species correlate with their relative neuronal toxicities. Together, our results demonstrate that maintaining a delicate balance not only between the monomeric forms of Aβ42 and Aβ40, but also the monomeric and aggregated forms of both peptides is essential for maintaining Aβ solubility and preventing Aβ fibrillogenesis and toxicity. Implications for AD pathogenesis and anti-amyloid therapeutics This results presented in this thesis provide novel insight into the mechanisms of Aβ aggregation, fibrillogenesis and toxicity, and have important implications for understanding the role of Aβ amyloid formation in AD pathogenesis and design of therapeutic strategies. Most importantly, our results linking Aβ toxicity to the growth and fibrillization of Aβ oligomers in presence of Aβ monomers, suggest that anti-Aβ therapeutic strategies, many of which are currently being tested in animal models or in clinical trials in AD patients, hold potential as promising disease modifying interventions. We contemplate that targeting the nucleated polymerization of amyloid forming proteins offers an exciting framework for development of anti-amyloid therapies for a host of neurodegenerative diseases characterized by pathological accumulation of aggregated proteins including AD, Parkinson's disease, and prion diseases.

EPFL2010

The adipocyte differentiation protein APMAP is an endogenous suppressor of Aβ production in the brain

Mitko Dimitrov, Patrick Fraering, Alexandre Matz, Sébastien Mosser, Justine Pascual, Bernard Schneider

The deposition of amyloid-beta (Aβ) aggregates in the brain is a major pathological hallmark of Alzheimer's disease (AD). Aβ is generated from the cleavage of C-terminal fragments of the amyloid precursor protein (APP-CTFs) by γ-secretase, an intramembrane-cleaving protease with multiple substrates, including the Notch receptors. Endogenous modulation of γ-secretase is pointed to be implicated in the sporadic, age-dependent form of AD. Moreover, specifically modulating Aβ production has become a priority for the safe treatment of AD because the inhibition of γ-secretase results in adverse effects that are related to impaired Notch cleavage. Here, we report the identification of the adipocyte differentiation protein APMAP as a novel endogenous suppressor of Aβ generation. We found that APMAP interacts physically with γ-secretase and its substrate APP. In cells, the partial depletion of APMAP drastically increased the levels of APP-CTFs, as well as uniquely affecting their stability, with the consequence being increased secretion of Aβ. In wild-type and APP/ presenilin 1 transgenic mice, partial adeno-associated virus-mediated APMAP knockdown in the hippocampus increased Aβ production by ∼20 and ∼55%, respectively. Together, our data demonstrate that APMAP is a negative regulator of Aβ production through its interaction with APP and γ-secretase. All observed APMAP phenotypes can be explained by an impaired degradation of APP-CTFs, likely caused by an altered substrate transport capacity to the lysosomal/autophagic system.

Oxford University Press2015

Middle-down approaches for mass spectrometry-based protein identification and characterization

Kristina Srzentic

Mass spectrometry (MS) has emerged over the last two decades as the analytical technique of choice in systems-level protein studies, known as proteomics. Two are the MS-based approaches generally applied to proteomics: bottom-up (BU), which relies on the proteolytic digestion of proteins into short (~10 amino acids) peptides, and top-down (TD), where proteolysis is omitted, intact proteins are detected and fragmented in gas phase. Both methods present advantages as well as drawbacks. Here, we sought to establish a complete platform to put forward a third MS-based proteomic approach; middle-down (MD). It implies protein digestion as in BU, but aims to generate large peptides which size approaches the one of small intact proteins that are readily analyzed in TD. This novel domain aims to account for the shortcoming of both classical approaches. Until now, the main reasons behind the limited use of MD proteomics have been the lack of easy-to-use cleaving agents capable of producing peptides in the desired 3-15 kDa mass range with high specificity, limitations in MS and allied instrumentation, and the absence of dedicated bioinformatics tools for processing of acquired data. The latter greatly impedes the next milestone in MD proteomics â large-scale analysis. MD can potentially combine the analysis of large portions of proteins carrying set of biologically-relevant modifications â allowing exploring proteins of molecular weight or complexity incompatible with current TD capabilities â with the high-throughput hallmark of BU proteomics. Here, we first in silico evaluated the potential target amino acid residues to produce peptides in the MD mass range within the proteomes of different organisms. This bioinformatics work was followed by an experimental study based on synthetic MD-sized peptides, aimed at determining the optimal MS and tandem MS parameters for large peptide characterization. Next, we pursued two distinct ways of performing MD proteolysis: i) the use of an enzyme and ii) the use of a chemical reagent. We selected the protease Sap9 as a target enzyme for MD, which we fully characterized and successfully applied to the study of a mixture of monoclonal antibodies, where it showed an advantage over traditional BU in terms of reduced introduction of artifacts to the sample, allowing the post-translational modification investigation and unambiguous antibody identification. The chemical cleavage way we addressed via judicious protocol optimization for hydrolysis at the N-terminal side of cysteine with NTCB reagent. We also advanced MD protocols by generation of large (~50 kDa) subunits of monoclonal antibodies through the use of papain and another more specific novel protease, GingisKHAN, combined with new MS signal processing and data analysis capabilities. The developed workflow improved mapping of the connectivity of cysteines involved in inter- and intra-molecular disulfide bridges in antibodies. To summarize, we demonstrated that MD approach to mass spectrometry and proteomics is a powerful, yet underdeveloped, complement to BU and TD. This work has benchmarked MD for targeted protein analysis. In the near future, with advancements of the field, we envision its growing use for large-scale complex proteome analysis.