Neil A. Ranson scite author profile

The aggregation of proteins into amyloid fibrils and their deposition into plaques and intracellular inclusions is the hallmark of amyloid disease. The accumulation and deposition of amyloid fibrils, collectively known as amyloidosis, is associated with many pathological conditions such as A disease P , type II diabetes, and dialysis related amyloidosis.However, elucidation of the atomic structure of amyloid fibrils formed from their intact protein precursors and how fibril formation relates to disease has remained elusive. Recent advances in structural biology techniques, including cryo-electron microscopy (cryo-EM) and solid state NMR (ssNMR), have finally broken this impasse. The first near-atomic resolution structures of amyloid fibrils formed in vitro, seeded from plaque material, and analysed directly ex vivo are now available.The results reveal cross- structures which are far more intricate than anticipated. Here, we describe these structures, highlighting their similarities and differences. We also discuss how amyloid structure may affect the ability of fibrils to spread to different sites in a prion-like manner, along with their roles in disease. These molecular insights will aid in understanding the development and spread of amyloid diseases and are inspiring new strategies for therapeutic intervention.

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Lateral opening in the intact β-barrel assembly machinery captured by cryo-EM

Iadanza

et al. 2016

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The β-barrel assembly machinery (BAM) is a ∼203 kDa complex of five proteins (BamA–E), which is essential for viability in E. coli. BAM promotes the folding and insertion of β-barrel proteins into the outer membrane via a poorly understood mechanism. Several current models suggest that BAM functions through a ‘lateral gating' motion of the β-barrel of BamA. Here we present a cryo-EM structure of the BamABCDE complex, at 4.9 Å resolution. The structure is in a laterally open conformation showing that gating is independent of BamB binding. We describe conformational changes throughout the complex and interactions between BamA, B, D and E, and the detergent micelle that suggest communication between BAM and the lipid bilayer. Finally, using an enhanced reconstitution protocol and functional assays, we show that for the outer membrane protein OmpT, efficient folding in vitro requires lateral gating in BAM.

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ATP-Bound States of GroEL Captured by Cryo-Electron Microscopy

Ranson

Farr

Roseman

et al. 2001

Cell

273

313

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The chaperonin GroEL drives its protein-folding cycle by cooperatively binding ATP to one of its two rings, priming that ring to become folding-active upon GroES binding, while simultaneously discharging the previous folding chamber from the opposite ring. The GroEL-ATP structure, determined by cryo-EM and atomic structure fitting, shows that the intermediate domains rotate downward, switching their intersubunit salt bridge contacts from substrate binding to ATP binding domains. These observations, together with the effects of ATP binding to a GroEL-GroES-ADP complex, suggest structural models for the ATP-induced reduction in affinity for polypeptide and for cooperativity. The model for cooperativity, based on switching of intersubunit salt bridge interactions around the GroEL ring, may provide general insight into cooperativity in other ring complexes and molecular machines.

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Location of a folding protein and shape changes in GroEL–GroES complexes imaged by cryo-electron microscopy

Chen

Roseman

Hunter

et al. 1994

Nature

340

265

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Protein folding mediated by the molecular chaperone GroEL occurs by its binding to non-native polypeptide substrates and is driven by ATP hydrolysis. Both of these processes are influenced by the reversible association of the co-protein, GroES (refs 2-4). GroEL and other chaperonin 60 molecules are large, cylindrical oligomers consisting of two stacked heptameric rings of subunits; each ring forms a cage-like structure thought to bind polypeptides in a central cavity. Chaperonins play a passive role in folding by binding or sequestering folding proteins to prevent their aggregation, but they may also actively unfold substrate proteins trapped in misfolded forms, enabling them to assume productive folding conformations. Biochemical studies show that GroES improves the efficiency of GroEL function, but the structural basis for this is unknown. Here we report the first direct visualization, by cryo-electron microscopy, of a non-native protein substrate (malate dehydrogenase) bound to the mobile, outer domains at one end of GroEL. Addition of GroES to GroEL in the presence of ATP causes a dramatic hinge opening of about 60 degrees. GroES binds to the equivalent surface of the GroEL outer domains, but on the opposite end of the GroEL oligomer to the protein substrate.

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Neil A. Ranson

A new era for understanding amyloid structures and disease

Lateral opening in the intact β-barrel assembly machinery captured by cryo-EM

ATP-Bound States of GroEL Captured by Cryo-Electron Microscopy

Location of a folding protein and shape changes in GroEL–GroES complexes imaged by cryo-electron microscopy

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