Benjamin Ryskeldi-Falcon

Pathological protein assembly in neurodegenerative diseases

bfalcon@mrc-lmb.cam.ac.uk
Personal group site

Ordered assembly of a small number of proteins within neurons and, in some cases, glia is a feature of neurodegenerative diseases. These proteins form amyloid structures enriched in repetitively stacked beta-strands. Mutations in the genes encoding these proteins lead to assembly and inherited neurodegenerative disease, demonstrating a causal role. Assemblies arise in discrete brain regions, from where they appear to propagate (spread and amplify) within connected brain networks, ultimately leading to neurodegeneration.

B Falcon Group webpage Fig1 — The background shows assembled tau inclusions within neurons and astrocytes (purple) in the neurodegenerative disease chronic traumatic encephalopathy (CTE). The foreground shows the major component of these inclusions, the CTE Type I tau filament, formed from two protofilaments (light and dark pink) centered around non-proteinaceous molecules (red).

We work to understand the molecular basis of protein assembly into amyloid in neurodegenerative disease. Key questions that interest us are: How do assemblies form and propagate? How does this contribute to nerve cell degeneration? Why are only some cell populations in the brain vulnerable? Why does selective vulnerability differ between diseases?

B Falcon Group Webpage Fig2 — Hypothesised stages in the transneuronal propagation of protein assemblies (blue) in neurodegenerative disease.

To answer these questions, we combine structural and cell biology, using high-resolution electron microscopy with patient samples and advanced models of assembly in neuronal and glial cells. Electron cryo-microscopy (cryo-EM) of filament structures from human brains revealed that tau assemblies exist as disease-specific conformers, formed from conserved secondary structure motifs with different turn conformations and non-proteinaceous components. We are now studying how these structures relate to selective cell vulnerability by focusing on the molecular interactions between assemblies and brain cells.

Selected Papers

Arseni, D., Nonaka, T., Jacobsen, M.H., Murzin, A.G., Cracco, L., Peak-Chew, S.Y., Garringer, H.J., Kawakami, I., Suzuki, H., Onaya, M., Saito, Y., Murayama, S., Geula, C., Vidal, R., Newell, K.L., Mesulam, M., Ghetti, B., Hasegawa, M., Ryskeldi-Falcon, B. (2024)
Heteromeric amyloid filaments of ANXA11 and TDP-43 in FTLD-TDP Type C
Nature10.1038/s41586-024-08024-5
Tetter, S., Arseni, D., Murzin, A.G., Buhidma, Y., Peak-Chew, S.Y., Garringer, H.J., Newell, K.L., Vidal, R., Apostolova, L.G., Lashley, T., Ghetti, B., Ryskeldi-Falcon, B. (2024)
TAF15 amyloid filaments in frontotemporal lobar degeneration
Nature 625(7994): 345-351
Scheres, S.H.W., Ryskeldi-Falcon, B., Goedert, M. (2023)
Molecular pathology of neurodegenerative diseases by cryo-EM of amyloids
Nature 621(7980): 701-710
Arseni, D., Chen, R., Murzin, A.G., Peak-Chew, S.Y., Garringer, H.J., Newell, K.L., Kametani, F., Robinson, A.C., Vidal, R., Ghetti, B., Hasegawa, M., Ryskeldi-Falcon, B. (2023)
TDP-43 forms amyloid filaments with a distinct fold in type A FTLD-TDP
Nature 620(7975): 898-903
Yang, Y., Arseni, D., Zhang, W., Huang, M., Lövestam, S., Schweighauser, M., Kotecha, A., Murzin, A.G., Peak-Chew, S.Y., Macdonald, J., Lavenir, I., Garringer, H.J., Gelpi, E., Newell, K.L., Kovacs, G.G., Vidal, R., Ghetti, B., Ryskeldi-Falcon, B., Scheres, S.H.W., Goedert, M. (2022)
Cryo-EM structures of amyloid-β 42 filaments from human brains
Science 375(6577): 167-172
Arseni, D., Hasegawa, M., Murzin, A.G., Kametani, F., Arai, M., Yoshida, M., Ryskeldi-Falcon, B. (2022)
Structure of pathological TDP-43 filaments from ALS with FTLD
Nature 601(7891): 139-143

Group Members

Heidy Chen
Ashling Giblin
Fred Hawkings
Stephan Tetter
Nikhil Varghese