Amyloidosis involves the extracellular deposition of proteinaceous amyloid fibrils and accessory molecules in organ(s) and/or tissue(s), and is associated with a host of human diseases, including Alzheimer disease, diabetes, and heart disease. Unfortunately, the amyloidoses are currently incurable, and there is an urgent need for less invasive diagnostics. To address this, we have generated 22 monoclonal antibodies (mAbs) against aggregates formed by a blood transport protein, transthyretin (TTR), which primarily forms amyloid fibrils in a patient's heart and/or peripheral nerves. Four of the mAbs, 2T5C9, 2G9C, T1F11, and TB2H7, demonstrated diagnostic potential in enzyme-linked immunosorbent assays (ELISA) by their low to sub-nanomolar cross-reactivity with recombinant wild-type (WT) and mutant TTR aggregates and lack of binding to native TTR or amyloid fibrils formed by other peptides or proteins. Notably, in the presence of normal human sera, three of the four mAbs, 2T5C9, 2G9C, and T1F11, retained low nM binding to TTR amyloid fibrils derived from two patients with familial amyloidotic polyneuropathy (FAP). The two most promising mAbs, 2T5C9 and 2G9C, were also shown by immunohistochemistry to have low nM binding to TTR amyloid deposits in cardiac tissue sections from two FAP patients. Taken together, these findings strongly support further investigations on the diagnostic utility of TTR aggregate specific mAbs for patients with TTR amyloidoses.
Soluble non-fibrillar assemblies of amyloid-beta (Aβ) and aggregated tau protein are the proximate synaptotoxic species associated with Alzheimer’s disease (AD). Anti-Aβ immunotherapy is a promising and advanced therapeutic strategy, but the precise Aβ species to target is not yet known. Previously, we and others have shown that natural human IgGs (NAbs) target diverse Aβ conformers and have therapeutic potential. We now demonstrate that these antibodies bound with nM avidity to conformational epitopes on plate-immobilized synthetic Aβ dimer assemblies, including synaptotoxic protofibrils, and targeted these conformers in solution. Importantly, NAbs also recognized Aβ extracted from the water-soluble phase of human AD brain, including species that migrated on denaturing PAGE as SDS-stable dimers. The critical reliance on Aβ’s conformational state for NAb binding, and not a linear sequence epitope, was confirmed by the antibody’s nM reactivity with plate-immobilized protofibrills, and weak uM binding to synthetic Aβ monomers and peptide fragments. The antibody’s lack of reactivity against a linear sequence epitope was confirmed by our ability to isolate anti-Aβ NAbs from intravenous immunoglobulin using affinity matrices, immunoglobulin light chain fibrils and Cibacron blue, which had no sequence similarity with the peptide. These findings suggest that further investigations on the molecular basis and the therapeutic/diagnostic potential of anti-Aβ NAbs are warranted.
Amyloid-reactive IgGs isolated from pooled blood of normal individuals (pAbs) have demonstrated clinical utility for amyloid diseases by in vivo targeting and clearing amyloidogenic proteins and peptides. We now report the following three novel findings on pAb conformer's binding to amyloidogenic aggregates: 1) pAb aggregates have greater activity than monomers (HMW species > dimers > monomers), 2) pAbs interactions with amyloidogenic aggregates at least partially involves unconventional (non-CDR) interactions of F(ab) regions, and 3) pAb's activity can be easily modulated by trace aggregates generated during sample processing. Specifically, we show that HMW aggregates and dimeric pAbs present in commercial preparations of pAbs, intravenous immunoglobulin (IVIg), had up to ~200- and ~7-fold stronger binding to aggregates of Aβ and transthyretin (TTR) than the monomeric antibody. Notably, HMW aggregates were primarily responsible for the enhanced anti-amyloid activities of Aβ- and Cibacron blue-isolated IVIg IgGs. Human pAb conformer's binding to amyloidogenic aggregates was retained in normal human sera, and mimicked by murine pAbs isolated from normal pooled plasmas. An unconventional (non-CDR) component to pAb's activity was indicated from control human mAbs, generated against non-amyloid targets, binding to aggregated Aβ and TTR. Similar to pAbs, HMW and dimeric mAb conformers bound stronger than their monomeric forms to amyloidogenic aggregates. However, mAbs had lower maximum binding signals, indicating that pAbs were required to saturate a diverse collection of binding sites. Taken together, our findings strongly support further investigations on the physiological function and clinical utility of the inherent anti-amyloid activities of monomeric but not aggregated IgGs.
from human brain extracts. Our ongoing work includes testing the hypothesis that post-translational modifications and co-associated proteins may contribute to the development and accumulation of toxic oligomer assemblies which are specific to demented patients versus nondemented patients with similar levels of A b oligomers.
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