The Structural Understanding of Transthyretin Misfolding and the Inspired Drug Approaches for the Treatment of Heart Failure Associated With Transthyretin Amyloidosis

He, Song; He, Xiaoli; Liu, Lei; Zhang, Wenbo; Yu, Lanlan; Deng, Zhun; Zhang, Feiyi; Mo, Shanshan; Fan, Yue; Zhao, Xinyue; Wang, Lun; Wang, Chenxuan; Zhang, Shuyang

doi:10.3389/fphar.2021.628184

Cited by 5 publications

(5 citation statements)

References 75 publications

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“…More than 130 mutational variants of transthyretin have been documented, with many showing associations for specific disease symptoms 4 . The influence of each mutational variant on the clinical phenotype is not yet fully understood, and some studies suggest that could be related to their effects on fibril formation, structure, or both 5,6 .…”

Section: Introductionmentioning

confidence: 99%

Amyloid fibril polymorphism in the heart of an ATTR amyloidosis patient with polyneuropathy attributed to the V122Δ variant

Ahmed,

Nguyen,

Afrin

et al. 2024

Preprint

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ATTR amyloidosis is a phenotypically heterogeneous disease characterized by the pathological deposition of transthyretin in the form of amyloid fibrils into various organs. ATTR amyloidosis may stem from mutations in variant (ATTRv) amyloidosis, or aging in wild-type (ATTRwt) amyloidosis. ATTRwt generally manifests as a cardiomyopathy phenotype, whereas ATTRv may present as polyneuropathy, cardiomyopathy, or mixed, in combination with many other symptoms deriving from secondary organ involvement. Over 130 different mutational variants of transthyretin have been identified, many of them being linked to specific disease symptoms. Yet, the role of these mutations in the differential disease manifestation remains elusive. Using cryo-electron microscopy, here we structurally characterized fibrils from the heart of an ATTRv patient carrying the V122Δ mutation, predominantly associated with polyneuropathy. Our results show that these fibrils are polymorphic, presenting as both single and double filaments. Our study alludes to a structural connection contributing to phenotypic variation in ATTR amyloidosis, as polymorphism in ATTR fibrils may manifest in patients with predominantly polyneuropathic phenotypes.

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Section: Introductionmentioning

confidence: 99%

Amyloid fibril polymorphism in the heart of an ATTR amyloidosis patient with polyneuropathy attributed to the V122Δ variant

Ahmed,

Nguyen,

Afrin

et al. 2024

Preprint

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“…This depends, of course, on the length of the amyloidogenic run of amino acids that forms it, but is typically 1-2nm or so. A protofibril consisting of 2-4 intertwined monomer fibrils may be 4-11nm for molecules such as Aβ [212], 7nm for tau [213], 11nm for the prion protein in its amyloid PrP Sc form [214], 6-15 nm for α-synuclein [215,216], and 7-13 nm for transthyretin [217].…”

Section: Size Of Fibres In Classical Amyloidoses and In Normal And Fi...mentioning

confidence: 99%

Proteomic evidence for amyloidogenic cross-seeding in fibrinaloid microclots

Kell,

Pretorius

2024

Preprint

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In classical amyloidoses, amyloid fibres form through the nucleation and accretion of protein monomers, with protofibrils and fibrils exhibiting a cross-β motif of parallel or antiparallel β-sheets oriented perpendicular to the fibre direction. These protofibrils and fibrils can intertwine to form mature amyloid fibres. Similar phenomena occur in blood from individuals with circulating inflammatory molecules (also those originating from viruses and bacteria). In the presence of inflammagens, pathological clotting can occur, that results in an anomalous amyloid form termed fibrinaloid microclots. Previous proteomic analyses of these microclots have shown the presence of non-fibrin(ogen) proteins, suggesting a more complex mechanism than simple entrapment. We provide evidence against a simple entrapment model, noting that clot pores are too large and centrifugation would have removed weakly bound proteins. Instead, we explore whether co-aggregation into amyloid fibres may involve axial (multiple proteins within the same fibril), lateral (single-protein fibrils contributing to a fibre), or both types of integration. Our analysis of proteomic data from fibrinaloid microclots in different diseases shows no significant overlap with the normal plasma proteome and no correlation between plasma protein abundance and presence in microclots. Notably, abundant plasma proteins like α-2-macroglobulin, fibronectin, and transthyretin are absent from microclots, while less abundant proteins such as adiponectin, periostin, and von Willebrand Factor are well represented. Using bioinformatic tools including AmyloGram and AnuPP, we found that proteins entrapped in fibrinaloid microclots exhibit high amyloidogenic tendencies, suggesting their integration as cross-β elements into amyloid structures. This integration likely contributes to the microclots’ resistance to proteolysis. Our findings underscore the role of cross-seeding in fibrinaloid microclot formation and highlight the need for further investigation into their structural properties and implications in thrombotic and amyloid diseases. These insights provide a foundation for developing novel diagnostic and therapeutic strategies targeting amyloidogenic cross-seeding in blood clotting disorders.

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“…Human TTR is a homotetrameric, slightly acidic (isoelectric point of 5.3) protein with a molecular mass of 55 kDa composed of four identical monomers, with a molecular weight of approximately 14 kDa [ 62 ]. Each monomer consists of eight β-strands structures designated with letters from “A” to “H” and one short α-helix of nine residues included between strands E and F. All strand interactions are antiparallel except for the interaction between strands A and G. These eight β-strands are connected by loops and are arranged in two groups of twisted β-sheets [ 44 , 63 , 64 ]. Interstrand hydrogen bonds allow the organisation of a tertiary structure of β-strands constituted by an inner (strands DAGH) and an outer (strands CBEF) β-sheet, which are orthogonal to one another [ 44 , 63 , 64 ] ( Figure 1 ).…”

Section: Ttr Structurementioning

confidence: 99%

“…Two TTR monomers are arranged into dimers by hydrogen bonding between two F (F, F’) and two H (H, H’) strands from adjacent monomers. This provides an extensive contact region where the β-sheets are strictly packed in a layer-by-layer manner contributing to the stability of the molecules [ 44 , 63 , 64 ].…”

Section: Ttr Structurementioning

confidence: 99%

“…Indeed, the dimer is thought to be the basic structural unit of mature TTR. This perspective is strengthened by the observation that the contact region between dimers is smaller than those between monomers and consists of hydrophobic and hydrophilic interactions [ 44 , 63 , 64 ]. Thus, in physiological conditions, TTR is a globular homo-tetramer organised as a dimer of dimers.…”

Section: Ttr Structurementioning

confidence: 99%

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The Journey of Human Transthyretin: Synthesis, Structure Stability, and Catabolism

et al. 2022

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Transthyretin (TTR) is a homotetrameric protein mainly synthesised by the liver and the choroid plexus whose function is to carry the thyroid hormone thyroxine and the retinol-binding protein bound to retinol in plasma and cerebrospinal fluid. When the stability of the tetrameric structure is lost, it breaks down, paving the way for the aggregation of TTR monomers into insoluble fibrils leading to transthyretin (ATTR) amyloidosis, a progressive disorder mainly affecting the heart and nervous system. Several TTR gene mutations have been characterised as destabilisers of TTR structure and are associated with hereditary forms of ATTR amyloidosis. The reason why also the wild-type TTR is intrinsically amyloidogenic in some subjects is largely unknown. The aim of the review is to give an overview of the TTR biological life cycle which is largely unknown. For this purpose, the current knowledge on TTR physiological metabolism, from its synthesis to its catabolism, is described. Furthermore, a large section of the review is dedicated to examining in depth the role of mutations and physiological ligands on the stability of TTR tetramers.

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The Structural Understanding of Transthyretin Misfolding and the Inspired Drug Approaches for the Treatment of Heart Failure Associated With Transthyretin Amyloidosis

Cited by 5 publications

References 75 publications

Amyloid fibril polymorphism in the heart of an ATTR amyloidosis patient with polyneuropathy attributed to the V122Δ variant

Amyloid fibril polymorphism in the heart of an ATTR amyloidosis patient with polyneuropathy attributed to the V122Δ variant

Proteomic evidence for amyloidogenic cross-seeding in fibrinaloid microclots

The Journey of Human Transthyretin: Synthesis, Structure Stability, and Catabolism

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