Scaling analysis reveals the mechanism and rates of prion replication in vivo

Meisl, Georg; Kurt, Timothy D.; Morales, Itzel Condado; Bett, Cyrus; Sorce, Silvia; Michaels, Thomas C. T.; Heinzer, Daniel; Avar, Merve; Cohen, Samuel I.; Hornemann, Simone; Aguzzi, Adriano; Dobson, Christopher M.; Sigurdson, Christina J.; Knowles, Tuomas P. J.

doi:10.1038/s41594-021-00565-x

Cited by 24 publications

(30 citation statements)

References 65 publications

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“…Moreover, neurons may be more effective at preventing replication when it occurs more slowly so that protective mechanisms are less easily overwhelmed. By contrast, we recently determined the replication rate of prions in mice (27) and found that it proceeds much faster in vitro than in vivo, indicating that in other mouse models, the effect of processes to inhibit aggregation in vivo can be much more pronounced than what we find in the mouse model analyzed here. Notably, the replication rate of prions in mice determined by Meisl et al (27) is very similar to that of tau in P301S mice determined here.…”

Section: Replication In Ad Is Orders Of Magnitude Slower Than In Mouse Models or In Vitrocontrasting

confidence: 84%

“…By contrast, we recently determined the replication rate of prions in mice (27) and found that it proceeds much faster in vitro than in vivo, indicating that in other mouse models, the effect of processes to inhibit aggregation in vivo can be much more pronounced than what we find in the mouse model analyzed here. Notably, the replication rate of prions in mice determined by Meisl et al (27) is very similar to that of tau in P301S mice determined here. This similarity may be due to the fact that the choice of the mutant and the level of protein expression is optimized for a life span of several months in the mouse models.…”

Section: Replication In Ad Is Orders Of Magnitude Slower Than In Mouse Models or In Vitrocontrasting

confidence: 84%

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In vivo rate-determining steps of tau seed accumulation in Alzheimer’s disease

et al. 2021

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Section: Replication In Ad Is Orders Of Magnitude Slower Than In Mouse Models or In Vitrocontrasting

confidence: 84%

Section: Replication In Ad Is Orders Of Magnitude Slower Than In Mouse Models or In Vitrocontrasting

confidence: 84%

In vivo rate-determining steps of tau seed accumulation in Alzheimer’s disease

et al. 2021

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“…Perhaps the physico-chemical environment in vivo allows only a limited number of strains to form de novo, and hence faithful strain transmission is not required in order to maintain strain homogeneity. There is, however, recent evidence that points toward the possibility that in cases where strain propagation is observed, most notably the mammalian prions, fragmentation could be the mechanism responsible for this propagation (Meisl et al, 2021). More research is needed to establish the degree of strain homogeneity in additional in vivo settings and to investigate the strain propagation of secondary nucleation for additional proteins and solution conditions that mimic in vivo conditions as closely as possible.…”

Section: Potential Origin Of the Differences In The Strain Propagation Properties Between Fibril Elongation And Secondary Nucleationmentioning

confidence: 99%

Secondary Nucleation and the Conservation of Structural Characteristics of Amyloid Fibril Strains

Alijanvand

Peduzzo

Buell

2021

Front. Mol. Biosci.

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Amyloid fibrils are ordered protein aggregates and a hallmark of many severe neurodegenerative diseases. Amyloid fibrils form through primary nucleation from monomeric protein, grow through monomer addition and proliferate through fragmentation or through the nucleation of new fibrils on the surface of existing fibrils (secondary nucleation). It is currently still unclear how amyloid fibrils initially form in the brain of affected individuals and how they are amplified. A given amyloid protein can sometimes form fibrils of different structure under different solution conditions in vitro, but often fibrils found in patients are highly homogeneous. These findings suggest that the processes that amplify amyloid fibrils in vivo can in some cases preserve the structural characteristics of the initial seed fibrils. It has been known for many years that fibril growth by monomer addition maintains the structure of the seed fibril, as the latter acts as a template that imposes its fold on the newly added monomer. However, for fibrils that are formed through secondary nucleation it was, until recently, not clear whether the structure of the seed fibril is preserved. Here we review the experimental evidence on this question that has emerged over the last years. The overall picture is that the fibril strain that forms through secondary nucleation is mostly defined by the solution conditions and intrinsic structural preferences, and not by the seed fibril strain.

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“…Following synthesis and glycosylation in the endoplasmic reticulum and Golgi, mature PrP C is present on the cell surface. PrP C is mainly found in rafts, membrane microdomains enriched in phospholipids and cholesterol [ 21 , 22 ]. Some PrP C molecules undergo proteolytic cleavage or membrane shedding (reviewed in [ 23 ]).…”

Section: Cell Biology Of Cellular Prpmentioning

confidence: 99%

Propagation and Dissemination Strategies of Transmissible Spongiform Encephalopathy Agents in Mammalian Cells

Heumüller

Hornberger

Hebestreit

et al. 2022

IJMS

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Transmissible spongiform encephalopathies or prion disorders are fatal infectious diseases that cause characteristic spongiform degeneration in the central nervous system. The causative agent, the so-called prion, is an unconventional infectious agent that propagates by converting the host-encoded cellular prion protein PrP into ordered protein aggregates with infectious properties. Prions are devoid of coding nucleic acid and thus rely on the host cell machinery for propagation. While it is now established that, in addition to PrP, other cellular factors or processes determine the susceptibility of cell lines to prion infection, exact factors and cellular processes remain broadly obscure. Still, cellular models have uncovered important aspects of prion propagation and revealed intercellular dissemination strategies shared with other intracellular pathogens. Here, we summarize what we learned about the processes of prion invasion, intracellular replication and subsequent dissemination from ex vivo cell models.

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Scaling analysis reveals the mechanism and rates of prion replication in vivo

Cited by 24 publications

References 65 publications

In vivo rate-determining steps of tau seed accumulation in Alzheimer’s disease

In vivo rate-determining steps of tau seed accumulation in Alzheimer’s disease

Secondary Nucleation and the Conservation of Structural Characteristics of Amyloid Fibril Strains

Propagation and Dissemination Strategies of Transmissible Spongiform Encephalopathy Agents in Mammalian Cells

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