A model for amyloid fibril formation in immunoglobulin light chains based on comparison of amyloidogenic and benign proteins and specific antibody binding

Khurana, Rohit; Souillac, Pierre O.; Coats, Alisa C.; Minert, Lauren J.; Ionescu-Zanetti, Cristian; Carter, Sue A.; Solomon, Alan; Fink, Anthony L.

doi:10.3109/13506120309041731

Cited by 23 publications

(26 citation statements)

References 37 publications

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“…Previous studies of SMA aggregation in solution in the absence of mica surfaces have shown that both fibrils and amorphous aggregates are found, depending on the conditions (14,32,33). When small wafers of mica are added to solutions of SMA at low concentration, a number of different types of deposit are observed on the mica (16).…”

Section: Comparison Of Aggregates Grown On Mica and In Solution-mentioning

confidence: 99%

Annular Oligomeric Amyloid Intermediates Observed by in Situ Atomic Force Microscopy

Zhu¹,

Han

Zhou

et al. 2004

Journal of Biological Chemistry

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Amyloidoses and related protein deposition diseases involve the transformation of normally soluble proteins into insoluble deposits, usually fibrillar in nature. Although it was originally assumed that the fibrils were the toxic species, this assumption has recently been called into question. Accumulating evidence in several systems suggests that oligomeric intermediates on the aggregation pathway may be toxic. In the present study we used in situ atomic force microscopy to monitor aggregation in aqueous solution in real time. The sample used was an amyloidogenic immunoglobulin light chain, involved in AL or light chain amyloidosis. The nature of the observed oligomeric intermediates was dependent on the conditions of incubation, especially pH and ionic strength. Several different aggregation intermediates with a variety of morphologies, including annular or torus-shaped species, were observed. The data indicate that protein aggregation can be very complex, involving a variety of different oligomeric intermediates whose population will be determined by the kinetic and thermodynamic competition between them.

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Section: Comparison Of Aggregates Grown On Mica and In Solution-mentioning

confidence: 99%

Annular Oligomeric Amyloid Intermediates Observed by in Situ Atomic Force Microscopy

Zhu¹,

Han

Zhou

et al. 2004

Journal of Biological Chemistry

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“…As evidenced, the epitope recognized by this antibody was present within the first 30 amino acids, and in studies of peptides encompassing this region (Figure 3a and b), it was further localized to the N-terminal 22 residues with an EC 50 of 0.24 ± 0.01 nM for Len , a value comparable to that of the intact V L (EC 50 , 0.18 ± 0.03 nM). Notably, there was no reactivity with Len (18)(19)(20)(21)(22)(23)(24)(25)(26)(27)(28)(29)(30). More precisely, the structure recognized by mAb 11-1F4 was contained within the N-terminal 18 residues (EC 50 Len (1-18), 0.30 ± 0.10 nM).…”

Section: Mab 11-1f Binds To a Conformational Epitope Located Within Fmentioning

confidence: 99%

“…Taken together, these data indicate that the epitope present on LC fibrils is associated with the formation of a fibril-prone structure, that is, an amyloidogenic intermediate. This conclusion is supported by the fact that mAb 11-1F4 is a potent inhibitor of de novo LC fibrillo-genesis at sub-equimolar concentrations (27,30). The fact that the epitope also could be detected on Other investigators have generated antibodies reactive with cryptic epitopes exposed on Aβ (12,(31)(32)(33)(34)(35), TTR (36), prion (37,38), and β2-microglobulin (39) fibrils and assembly intermediates but not on the native precursors.…”

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confidence: 91%

Localization of a Conformational Epitope Common to Non-Native and Fibrillar Immunoglobulin Light Chains

et al. 2007

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Amyloid fibrils and partially unfolded intermediates may be distinguished serologically from native amyloidogenic precursor proteins or peptides. In this regard, we had previously reported that the IgG1 mAb 11-1F4, generated by immunizing mice with a thermally denatured variable region fragment of the human Igκ4 Bence Jones protein Len, reacted specifically with light chain (LC) fibrils, irrespective of κ or λ isotype but, notably, did not with native molecules (Hrncic, R. et al. (2000) Am. J. Pathol. 157, 1239Pathol. 157, -1246. To elucidate the molecular basis of this specificity, we have used a europium-linked fluorescent immunoassay, where it was demonstrated through epitope mapping that mAb 11-1F4 recognizes a conformational determinant contained within the first (Nterminal) 18 amino acids of misfolded LCs. The nature of this epitope was evidenced in competition studies where the peptide Len (1-18), but not the intact protein or other LCs, inhibited the binding of the antibody to fibrils. This unique reactivity was dependent on the structural integrity of this portion of the molecule, particularly the presence of a highly conserved prolyl residue at position 8. On the basis of our experimental data, we posit that the mAb 11-1F4 binding site found on partially denatured and fibrillar LCs involves an inducible N-terminal main chain reversal that results in the formation of a proline anchored β-turn. Our delineation of this LC fibril-associated epitope provides the rationale for the design of novel amyloid-reactive antibodies with diagnostic and therapeutic potential for patients with LC-associated and other forms of amyloidosis. Amyloidogenesis involves a process by which normally soluble proteins or peptides form nonnative intermediates that eventually assemble into fibrils (1). All types of amyloid, regardless of amino acid sequence, share common tertiary structural features, that is, they are comprised of extended β-sheets oriented perpendicularly to the long fibril axis (2,3) and possess sites that bind the dyes thioflavin T (ThT1) and Congo red (4,5). Additionally, these components and their assembly precursors, irrespective of primary structure, contain generic conformational epitopes not present on native molecules (6-12), further indicating their physical homogeneity.The common epitopes present on amyloid fibrils and their intermediates offer targets for the design of novel diagnostic and therapeutic reagents. In this regard, we have generated a murine monoclonal antibody (mAb), designated 11-1F4 (13), which reacts specifically with light chain (LC) fibrils, but not soluble proteins, and has been shown in an experimental in vivo model to accelerate the removal of amyloidomas composed of human LC fibrils, an effect independent of the κ or λ isotype or the V L subgroup (9). This mAb was generated using as immunogen a heat-aggregated suspension of the human κ4 variable domain (V L ) Len (13,14) To localize and determine the nature of the neo-antigen recognized on conformationally altered LCs by...

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“…The fact that the majority of light chains are resistant to amyloid formation has allowed comparisons of amyloidogenic and nonamyloidogenic V L domains to attempt to identify the cause of this predisposition. [34][35][36][37][38][39] It has been suggested that the formation of amyloid fibrils does not begin from the native state of a protein, but more likely from a partially folded state or an intermediate state. [40][41][42] Mutations and changes in conditions that lead to destabilisation of the native state may therefore serve to increase the population of an intermediate state, thereby enabling more molecules to be diverted into an amyloid-forming pathway.…”

Section: Introductionmentioning

confidence: 99%

The Folding Pathway of the Antibody VL Domain

Simpson

Herold

Büchner

2009

Journal of Molecular Biology

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A model for amyloid fibril formation in immunoglobulin light chains based on comparison of amyloidogenic and benign proteins and specific antibody binding

Cited by 23 publications

References 37 publications

Annular Oligomeric Amyloid Intermediates Observed by in Situ Atomic Force Microscopy

Annular Oligomeric Amyloid Intermediates Observed by in Situ Atomic Force Microscopy

Localization of a Conformational Epitope Common to Non-Native and Fibrillar Immunoglobulin Light Chains

The Folding Pathway of the Antibody VL Domain

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