Studies on unfolded β2-microglobulin at C-terminal in dialysis-related amyloidosis

The Early Phase of β2m Aggregation: An Integrative Computational Study Framed on the D76N Mutant and the ΔN6 Variant

Human β2-microglobulin (b2m) protein is classically associated with dialysis-related amyloidosis (DRA). Recently, the single point mutant D76N was identified as the causative agent of a hereditary systemic amyloidosis affecting visceral organs. To get insight into the early stage of the β2m aggregation mechanism, we used molecular simulations to perform an in depth comparative analysis of the dimerization phase of the D76N mutant and the ΔN6 variant, a cleaved form lacking the first six N-terminal residues, which is a major component of ex vivo amyloid plaques from DRA patients. We also provide first glimpses into the tetramerization phase of D76N at physiological pH. Results from extensive protein–protein docking simulations predict an essential role of the C- and N-terminal regions (both variants), as well as of the BC-loop (ΔN6 variant), DE-loop (both variants) and EF-loop (D76N mutant) in dimerization. The terminal regions are more relevant under acidic conditions while the BC-, DE- and EF-loops gain importance at physiological pH. Our results recapitulate experimental evidence according to which Tyr10 (A-strand), Phe30 and His31 (BC-loop), Trp60 and Phe62 (DE-loop) and Arg97 (C-terminus) act as dimerization hot-spots, and further predict the occurrence of novel residues with the ability to nucleate dimerization, namely Lys-75 (EF-loop) and Trp-95 (C-terminus). We propose that D76N tetramerization is mainly driven by the self-association of dimers via the N-terminus and DE-loop, and identify Arg3 (N-terminus), Tyr10, Phe56 (D-strand) and Trp60 as potential tetramerization hot-spots.

C-terminal unfolding of an amyloidogenic β2-microglobulin fragment: ΔN6β2-microglobulin

OBJECTIVES

A β2-microglobulin (β2m) fragment that lacks the first six amino acids, i.e., ΔN6β2-microglobulin (ΔN6β2m), is an endogenous, proteolytically derived, amyloidogenic fragment of β2m, the precursor protein in Aβ2M amyloidosis (dialysis-related amyloidosis). As reports suggest the importance of C-terminal unfolding for the amyloidogenicity of β2m, in this study we aimed to investigate conformational characteristics of ΔN6β2m related to amyloidogenicity. We also measured the concentration of an amyloidogenic intermediate of β2m with C-terminal unfolding (β2m92-99) in serum samples from 10 patients undergoing hemodialysis (HD).

METHODS

We utilized capillary electrophoretic analysis, surface plasmon resonance and enzyme-linked immunosorbent assay.

RESULTS AND CONCLUSIONS

We confirmed the normal core structure of ΔN6β2m with a commercial monoclonal anti-β2m antibody. In addition, using the specific monoclonal antibody for the C-terminal peptide, i.e. mAb 92-99, we confirmed unfolding in the C-terminal region of ΔN6β2m. On the basis of these findings, we established an ELISA to measure β2m92-99 using ΔN6β2m as a standard molecule in circulation. However, we did not detect β2m92-99 in serum from 10 HD patients, despite the absence of uremic inhibitors in the serum.

Role of conformational change in the C-terminus of beta2-microglobulin in dialysis-related amyloidosis

BACKGROUND

Beta(2)-microglobulin (beta(2)m) has been identified as the precursor protein of dialysis-related amyloidosis (DRA), which is a serious complication for haemodialysis (HD) patients. However, mechanisms underlying beta(2)m amyloid fibril formation remains to be elucidated. We previously demonstrated, in amyloid deposits from HD patients, a conformational isoform of beta(2)m with an unfolded C-terminus. However, no direct experiments have previously been performed to address whether unfolded beta(2)m in the C-terminus may be prone to form amyloid fibrils.

METHODS

To evaluate roles of C-terminal amino acids in beta(2)m-induced amyloid formation, we generated six types of recombinant beta(2)m with amino acid substitutions in the C-terminal region. To investigate their conformational change and amyloidogenicity, we measured circular dichroism spectra, the fluorescence intensity of tryptophan and thioflavin-T (ThT) of the recombinant beta(2)m. To analyse morphological change of beta(2)m, we performed electron microscopy (EM) on the samples with elevated ThT fluorescence intensity. We used ultrasonication to enhance beta(2)m destabilization of the protein.

RESULTS

Beta(2)M Trp95Leu and Arg97Ala showed conformational changes and increased their amyloidgenicity compared with beta(2)m wild-type (WT). With ultrasonication, beta(2)m Trp95Leu and Arg97Ala generated more amyloid fibrils than did beta(2)m WT even in physiological solution. EM showed that beta(2)m formed amorphous debris containing typical amyloid fibrils at 24 hours, when ThT fluorescence intensity was three-fold lower than that at six hours.

CONCLUSIONS

Conformational changes in the C-terminus of beta(2)m may play an important role in DRA and that ultrasonication is useful for analysis of beta(2)m amyloidogenesis.