Gergely Agócs scite author profile

There are proteins that are built of two structural domains and are deposited full-length in amyloid plaques formed in various diseases. In spite of the known differences in the mechanisms of folding of single- and multidomain proteins, no published studies can be found that address the role of the domain-domain interactions during misfolding and amyloid formation. By the discovery of the role of domain-domain interactions, here we provide important insight in the submolecular mechanism of amyloid formation. A model system based on yeast phosphoglycerate kinase was designed. This system includes the wild-type yeast phosphoglycerate kinase and single-tryptophan mutants of the individual N and C terminal domains and the complete protein. Electron microscopic measurements proved that amyloid fibrils grow from all mutants under identical conditions as for the wild-type protein. Misfolding and amyloid formation was followed in stopped-flow and manual mixing experiments on the 1 ms to 4 days timescale. Tryptophan fluorescence was used for selective detection of conformational changes accompanying the formation of the amyloidogenic intermediates and the growth of amyloid fibrils. The interactions between the polypeptide chains of the two domains direct the misfolding process from the early steps to the amyloid formation, and influence the final structure. The kinetics of misfolding is different for the individual domains, pointing to the significance of the amino acid sequence. Misfolding of the domains within the complete protein is synchronized indicating that domain-domain interactions direct the misfolding and amyloid formation mechanism.

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Recovery of functional enzyme from amyloid fibrils

Agócs

Solymosi

Varga

et al. 2010

FEBS Letters

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a b s t r a c tAmyloid deposits, which accumulate in numerous diseases, are the final stage of multi-step protein conformational-conversion and oligomerization processes. The underlying molecular mechanisms are not fully understood, and particularly little is known about the reverse reaction. Here we show that phosphoglycerate kinase amyloid fibrils can be converted back into native protein. We achieved recovery with 60% efficiency, which is comparable to the success rate of the unfolding-refolding studies, and the recovered enzyme was folded, stable and fully active. The key intermediate stages in the recovery process are fibril disassembly and unfolding followed by spontaneous protein folding.

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Label-free Multiscale Transport Imaging of the Living Cell

Osváth

Herényi

Agócs

et al. 2018

Biophysical Journal

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The living cell is characterized by a myriad of parallel intracellular transport processes. Simultaneously capturing their global features across multiple temporal and spatial scales is a nearly unsurmountable task. Here we present a method that enables the microscopic imaging of the entire spectrum of intracellular transport on a broad time scale without the need for prior labeling. We show that from the time-dependent fluctuation of pixel intensity, in either bright-field or phase-contrast microscopic images, a scaling factor can be derived that reflects the local Hurst coefficient (H), the value of which reveals the microscopic mechanisms of intracellular motion. The Hurst coefficient image of the interphase cell displays an unexpected, overwhelming superdiffusion (H > 0.5) in the cytoplasm and subdiffusion (H < 0.5) in the nucleus, and provides unprecedented sensitivity in detecting transport processes associated with the living state.

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Comparing the Folding and Misfolding Energy Landscapes of Phosphoglycerate Kinase

Agócs¹,

Szabó²,

Köhler³

et al. 2011

Biophysical Journal

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granule where it is stored. Our studies have shown zinc, which is found at millimolar concentrations in the secretory granule, significantly inhibits hIAPP amyloid fibrillogenesis at concentrations similar to those found in the extracellular environment. We show here by ITC and PICUP cross-linking that zinc binds to a complex of several hIAPP peptides at micromolar concentrations similar to those found in the extracellular environment, and in the process, promotes the formation of small IAPP oligomers. Interestingly, this observed interaction is unique to the hIAPP as membrane disrupting peptides with similar sequences exhibit minimal interaction with zinc. By contrast, the fibrillar amyloid form of hIAPP has only low affinity for zinc. High-resolution NMR structures of hIAPP bound to zinc reveal changes in along residues that would be located along one face of the hIAPP alpha-helix proposed as an intermediate for amyloid formation. These changes occur on the hydrophilic side of the amphipathic alpha-helix, away from the proposed interface for amyloid nucleation on the hydrophobic side. Combined, these results suggest zinc promotes the formation of off-pathway oligomers while creating a thermodynamic barrier for the formation of amyloid fibers.

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Comparing the Folding and Misfolding Energy Landscapes of Phosphoglycerate Kinase

Agócs

Szabó

Köhler

et al. 2012

Biophysical Journal

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Partitioning of polypeptides between protein folding and amyloid formation is of outstanding pathophysiological importance. Using yeast phosphoglycerate kinase as model, here we identify the features of the energy landscape that decide the fate of the protein: folding or amyloidogenesis. Structure formation was initiated from the acid-unfolded state, and monitored by fluorescence from 10 ms to 20 days. Solvent conditions were gradually shifted between folding and amyloidogenesis, and the properties of the energy landscape governing structure formation were reconstructed. A gradual transition of the energy landscape between folding and amyloid formation was observed. In the early steps of both folding and misfolding, the protein searches through a hierarchically structured energy landscape to form a molten globule in a few seconds. Depending on the conditions, this intermediate either folds to the native state in a few minutes, or forms amyloid fibers in several days. As conditions are changed from folding to misfolding, the barrier separating the molten globule and native states increases, although the barrier to the amyloid does not change. In the meantime, the native state also becomes more unstable and the amyloid more stable. We conclude that the lower region of the energy landscape determines the final protein structure.

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Gergely Agócs

Domain interactions direct misfolding and amyloid formation of yeast phosphoglycerate kinase

Recovery of functional enzyme from amyloid fibrils

Label-free Multiscale Transport Imaging of the Living Cell

Comparing the Folding and Misfolding Energy Landscapes of Phosphoglycerate Kinase

Comparing the Folding and Misfolding Energy Landscapes of Phosphoglycerate Kinase

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