Transthyretin (TTR) amyloid fibril formation is observed during partial acid denaturation and while refolding acid-denatured TTR, implying that amyloid fibril formation results from the self-assembly of a conformational intermediate. The acid denaturation pathway of TTR has been studied in detail herein employing a variety of biophysical methods to characterize the intermediate(s) capable of amyloid fibril formation. At physiological concentrations, tetrameric TTR remains associated from pH 7 to pH 5 and is incapable of amyloid fibril formation. Tetrameric TTR dissociates to a monomer in a process that is dependent on both pH and protein concentration below pH 5. The extent of amyloid fibril formation correlates with the concentration of the TTR monomer having an altered, but defined, tertiary structure over the pH range of 5.0-3.9. The inherent Trp fluorescence-monitored denaturation curve of TTR exhibits a plateau over the pH range where amyloid fibril formation is observed (albeit at a higher concentration), implying that a steady-state concentration of the amyloidogenic intermediate with an altered tertiary structure is being detected. Interestingly, 1-anilino-8-naphthalenesulfonate fluorescence is at a minimum at the pH associated with maximal amyloid fibril formation (pH 4.4), implying that the amyloidogenic intermediate does not have a high extent of hydrophobic surface area exposed, consistent with a defined tertiary structure. Transthyretin has two Trp residues in its primary structure, Trp-41 and Trp-79, which are conveniently located far apart in the tertiary structure of TTR. Replacement of each Trp with Phe affords two single Trp containing variants which were used to probe local pH-dependent tertiary structural changes proximal to these chromophores. The pH-dependent fluorescence behavior of the Trp-79-Phe mutant strongly suggests that Trp-41 is located near the site of the tertiary structural rearrangement that occurs in the formation of the monomeric amyloidogenic intermediate, likely involving the C-strand-loop-D-strand region. Upon further acidification of TTR (below pH 4.4), the structurally defined monomeric amyloidogenic intermediate begins to adopt alternative conformations that are not amyloidogenic, ultimately forming an A-state conformation below pH 3 which is also not amyloidogenic. In summary, analytical equilibrium ultracentrifugation, SDS-PAGE, far- and near-UV CD, fluorescence, and light scattering studies suggest that the amyloidogenic intermediate is a monomeric predominantly beta-sheet structure having a well-defined tertiary structure.
Partial denaturation of transthyretin is sufficient for amyloid fibril formation in vitro
Amyloid diseases are caused by the self-assembly of a given protein into an insoluble cross-beta-sheet quaternary structural form which is pathogenic. An understanding of the biochemical mechanism of amyloid fibril formation should prove useful in understanding amyloid disease. Toward this end, a procedure for the conversion of the amyloidogenic protein transthyretin into amyloid fibrils under conditions which mimic the acidic environment of a lysosome has been developed. Association of a structured transthyretin denaturation intermediate is sufficient for amyloid fibril formation in vitro. The rate of fibril formation is pH dependent with significant rates being observed at pHs accessible within the lysosome (3.6-4.8). Far-UV CD spectroscopic studies suggest that transthyretin retains its secondary structural features at pHs where fibrils are formed. Near-UV CD studies demonstrate that transthyretin has retained the majority of its tertiary structure during fibril formation as well. Near-UV CD analysis in combination with glutaraldehyde cross-linking studies suggests that a pH-mediated tetramer to monomer transition is operative in the pH range where fibril formation occurs. The rate of fibril formation decreases markedly at pHs below pH 3.6, consistent with denaturation to a monomeric TTR intermediate which has lost its native tertiary structure and capability to form fibrils. It is difficult to specify with certainty which quaternary structural form of transthyretin is the amyloidogenic intermediate at this time. These difficulties arise because the maximal rate of fibril formation occurs at pH 3.6 where tetramer, traces of dimer, and significant amounts of monomer are observed.(ABSTRACT TRUNCATED AT 250 WORDS)
Structural Basis of Protein Kinetic Stability: Resistance to Sodium Dodecyl Sulfate Suggests a Central Role for Rigidity and a Bias Toward β-Sheet Structure
The term kinetic stability is used to describe proteins that are trapped in a specific conformation because of an unusually high-unfolding barrier that results in very slow unfolding rates. Motivated by the observation that some proteins are resistant to sodium dodecyl sulfate (SDS)-induced denaturation, an attempt was made to determine whether this property is a result of kinetic stability. We studied many proteins, including a few kinetically stable proteins known to be resistant to SDS. The resistance to SDS-induced denaturation was investigated by comparing the migration on polyacrylamide gels of identical boiled and unboiled protein samples containing SDS. On the basis of the different migration of these samples, eight proteins emerged as being resistant to SDS. The kinetic stability of these proteins was confirmed by their slow unfolding rate upon incubation in guanidine hydrochloride. Further studies showed that these proteins were also extremely resistant to proteolysis by proteinase K, suggesting that a common mechanism may account for their resistance to SDS and proteolytic cleavage. Together, these observations suggest that a rigid protein structure may be the physical basis for kinetic stability and that resistance to SDS may serve as a simple assay for identifying proteins whose native conformations are kinetically trapped. Remarkably, most of the kinetically stable SDS-resistant proteins in this study are oligomeric beta-sheet proteins, suggesting a bias of these types of structures toward kinetic stability.
Comparison of Lethal and Nonlethal Transthyretin Variants and Their Relationship to Amyloid Disease
The role that transthyretin (TTR) mutations play in the amyloid disease familial amyloid polyneuropathy (FAP) has been probed by comparing the biophysical properties of several TTR variants as a function of pH. We have previously demonstrated that the partial acid denaturation of TTR is sufficient to effect amyloid fibril formation by self-assembly of a denaturation intermediate which appears to be monomeric. Earlier studies on the most pathogenic FAP variant known, Leu-55-Pro, revealed that this variant is much less stable toward acid denaturation than wild-type TTR, apparently explaining why this variant can form amyloid fibrils under mildly acidic conditions where wild-type TTR remains nonamyloidogenic. The hypothesis that FAP mutations destabilize the TTR tetramer in favor of a monomeric amyloidogenic intermediate under lysosomal (acidic) conditions is further supported by the data described here. We compare the acid stability and amyloidogenicity of the most prevalent FAP variant, Val-30-Met, along with the double mutant, Val-30-Met/Thr-119-Met, which serves to model the effects of these mutations in heterozygous patients where the mutations are in different subunits. In addition, we have characterized the Thr-119-Met TTR variant, which is a common nonpathogenic variant in the Portuguese population, to further investigate the role that this mutation plays in protecting individuals who also carry the Val-30-Met mutation against the classically severe FAP pathology. This biophysical study demonstrates that Val-30-Met TTR is significantly less stable toward acid denaturation and more amyloidogenic than wild-type TTR, which in turn is less stable and more amyloidogenic than Thr-119-Met TTR. Interestingly, the double mutant Val-30-Met/Thr-119-Met is very similar to wild-type TTR in terms of its stability toward acid denaturation and its amyloidogenicity. The data suggest that the Thr-119-Met mutation confers decreased amyloidogenicity by stabilizing tetrameric TTR toward acid denaturation. In addition, fluorescence studies monitoring the acid-mediated denaturation pathways of several TTR variants reveal that the majority exhibit a plateau in the relative fluorescence intensity over the amyloid-forming pH range, i.e., ca. pH 4.3-3.3. This intensity plateau suggests that the amyloidogenic intermediate(s) is (are) being observed over this pH range. The Thr-119-Met variant does not exhibit this plateau presumably because the amyloidogenic intermediate(s) do(es) not build up in concentration in this variant. The intermediate is undoubtedly forming in the Thr-119-Met variant, as it will form amyloid fibrils at high concentrations; however, the intermediate is only present at a low steady-state concentration which makes it difficult to detect.
Transthyretin mutation Leu-55-Pro significantly alters tetramer stability and increases amyloidogenicity
A recently reported variant of human transthyretin (TTR), Leu-55-Pro, implicated as the causative agent in early-onset familial amyloid polyneuropathy was expressed and characterized, and its denaturation pathway and amyloidogenicity were compared to those of wild-type transthyretin. The overlap-extension polymerase chain reaction (PCR) methodology was used to introduce the Leu-55-Pro mutation into the transthyretin DNA sequence and to construct a new expression system. The Leu-55-Pro variant of transthyretin was expressed with a leader sequence to ensure secretion into the periplasmic space of Escherichia coli. Transthyretin's resistance to sodium dodecyl sulfate- (SDS-) induced denaturation was utilized to measure the quaternary stability as a function of pH employing SDS-polyacrylamide gel electrophoresis (PAGE) in the presence and absence of an amyloid fibril inhibitor, Z 3-14. These studies reveal that the Leu-55-Pro TTR tetramer is significantly less stable than wild-type TTR. This is relevant because we have previously shown that the partial denaturation of transthyretin is sufficient to effect amyloid fibril formation from a denaturation intermediate which may be a structured monomer. The ability of Leu-55-Pro TTR to denature to the amyloidogenic intermediate at pHs where the wild-type protein is stable may explain the variant's propensity to form amyloid fibrils in vitro and in vivo where the wild-type protein remains stable and nonamyloidogenic. Congo red binding, polarized light microscopy, and electron microscopy confirm the characteristic structure of amyloid fibrils produced from Leu-55-Pro TTR in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)
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