Structure-specific amyloid precipitation in biofluids

M. Rodrigues; P. Bhattacharjee; A. Brinkmalm; D.T. Do; C.M. Pearson; S. De; A. Ponjavic; J.A. Varela; K. Kulenkampff; I. Baudrexel; D. Emin; F.S. Ruggeri; J.E. Lee; A.R. Carr; T.P.J. Knowles; H. Zetterberg; T.N. Snaddon; S. Gandhi; S.F. Lee; D. Klenerman

doi:10.1038/s41557-022-00976-3

Structure-specific amyloid precipitation in biofluids

M. Rodrigues, P. Bhattacharjee, A. Brinkmalm, D.T. Do, C.M. Pearson, S. De, A. Ponjavic, J.A. Varela, K. Kulenkampff, I. Baudrexel, D. Emin, F.S. Ruggeri, J.E. Lee, A.R. Carr, T.P.J. Knowles, H. Zetterberg, T.N. Snaddon, S. Gandhi, S.F. Lee^*, D. Klenerman

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

16 Citations (Scopus)

Abstract

The composition of soluble toxic protein aggregates formed in vivo is currently unknown in neurodegenerative diseases, due to their ultra-low concentration in human biofluids and their high degree of heterogeneity. Here we report a method to capture amyloid-containing aggregates in human biofluids in an unbiased way, a process we name amyloid precipitation. We use a structure-specific chemical dimer, a Y-shaped, bio-inspired small molecule with two capture groups, for amyloid precipitation to increase affinity. Our capture molecule for amyloid precipitation (CAP-1) consists of a derivative of Pittsburgh Compound B (dimer) to target the cross β-sheets of amyloids and a biotin moiety for surface immobilization. By coupling CAP-1 to magnetic beads, we demonstrate that we can target the amyloid structure of all protein aggregates present in human cerebrospinal fluid, isolate them for analysis and then characterize them using single-molecule fluorescence imaging and mass spectrometry. Amyloid precipitation enables unbiased determination of the molecular composition and structural features of the in vivo aggregates formed in neurodegenerative diseases. [Figure not available: see fulltext.]

Original language	English
Pages (from-to)	1045-1053
Journal	Nature Chemistry
Volume	14
Issue number	9
Early online date	7 Jul 2022
DOIs	https://doi.org/10.1038/s41557-022-00976-3
Publication status	Published - Sept 2022

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Rodrigues, M., Bhattacharjee, P., Brinkmalm, A., Do, D. T., Pearson, C. M., De, S., Ponjavic, A., Varela, J. A., Kulenkampff, K., Baudrexel, I., Emin, D., Ruggeri, F. S., Lee, J. E., Carr, A. R., Knowles, T. P. J., Zetterberg, H., Snaddon, T. N., Gandhi, S., Lee, S. F., & Klenerman, D. (2022). Structure-specific amyloid precipitation in biofluids. Nature Chemistry, 14(9), 1045-1053. https://doi.org/10.1038/s41557-022-00976-3

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abstract = "The composition of soluble toxic protein aggregates formed in vivo is currently unknown in neurodegenerative diseases, due to their ultra-low concentration in human biofluids and their high degree of heterogeneity. Here we report a method to capture amyloid-containing aggregates in human biofluids in an unbiased way, a process we name amyloid precipitation. We use a structure-specific chemical dimer, a Y-shaped, bio-inspired small molecule with two capture groups, for amyloid precipitation to increase affinity. Our capture molecule for amyloid precipitation (CAP-1) consists of a derivative of Pittsburgh Compound B (dimer) to target the cross β-sheets of amyloids and a biotin moiety for surface immobilization. By coupling CAP-1 to magnetic beads, we demonstrate that we can target the amyloid structure of all protein aggregates present in human cerebrospinal fluid, isolate them for analysis and then characterize them using single-molecule fluorescence imaging and mass spectrometry. Amyloid precipitation enables unbiased determination of the molecular composition and structural features of the in vivo aggregates formed in neurodegenerative diseases. [Figure not available: see fulltext.]",

author = "M. Rodrigues and P. Bhattacharjee and A. Brinkmalm and D.T. Do and C.M. Pearson and S. De and A. Ponjavic and J.A. Varela and K. Kulenkampff and I. Baudrexel and D. Emin and F.S. Ruggeri and J.E. Lee and A.R. Carr and T.P.J. Knowles and H. Zetterberg and T.N. Snaddon and S. Gandhi and S.F. Lee and D. Klenerman",

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Rodrigues, M, Bhattacharjee, P, Brinkmalm, A, Do, DT, Pearson, CM, De, S, Ponjavic, A, Varela, JA, Kulenkampff, K, Baudrexel, I, Emin, D, Ruggeri, FS, Lee, JE, Carr, AR, Knowles, TPJ, Zetterberg, H, Snaddon, TN, Gandhi, S, Lee, SF & Klenerman, D 2022, 'Structure-specific amyloid precipitation in biofluids', Nature Chemistry, vol. 14, no. 9, pp. 1045-1053. https://doi.org/10.1038/s41557-022-00976-3

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T1 - Structure-specific amyloid precipitation in biofluids

AU - Rodrigues, M.

AU - Bhattacharjee, P.

AU - Brinkmalm, A.

AU - Do, D.T.

AU - Pearson, C.M.

AU - De, S.

AU - Ponjavic, A.

AU - Varela, J.A.

AU - Kulenkampff, K.

AU - Baudrexel, I.

AU - Emin, D.

AU - Ruggeri, F.S.

AU - Lee, J.E.

AU - Carr, A.R.

AU - Knowles, T.P.J.

AU - Zetterberg, H.

AU - Snaddon, T.N.

AU - Gandhi, S.

AU - Lee, S.F.

AU - Klenerman, D.

PY - 2022/9

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N2 - The composition of soluble toxic protein aggregates formed in vivo is currently unknown in neurodegenerative diseases, due to their ultra-low concentration in human biofluids and their high degree of heterogeneity. Here we report a method to capture amyloid-containing aggregates in human biofluids in an unbiased way, a process we name amyloid precipitation. We use a structure-specific chemical dimer, a Y-shaped, bio-inspired small molecule with two capture groups, for amyloid precipitation to increase affinity. Our capture molecule for amyloid precipitation (CAP-1) consists of a derivative of Pittsburgh Compound B (dimer) to target the cross β-sheets of amyloids and a biotin moiety for surface immobilization. By coupling CAP-1 to magnetic beads, we demonstrate that we can target the amyloid structure of all protein aggregates present in human cerebrospinal fluid, isolate them for analysis and then characterize them using single-molecule fluorescence imaging and mass spectrometry. Amyloid precipitation enables unbiased determination of the molecular composition and structural features of the in vivo aggregates formed in neurodegenerative diseases. [Figure not available: see fulltext.]

AB - The composition of soluble toxic protein aggregates formed in vivo is currently unknown in neurodegenerative diseases, due to their ultra-low concentration in human biofluids and their high degree of heterogeneity. Here we report a method to capture amyloid-containing aggregates in human biofluids in an unbiased way, a process we name amyloid precipitation. We use a structure-specific chemical dimer, a Y-shaped, bio-inspired small molecule with two capture groups, for amyloid precipitation to increase affinity. Our capture molecule for amyloid precipitation (CAP-1) consists of a derivative of Pittsburgh Compound B (dimer) to target the cross β-sheets of amyloids and a biotin moiety for surface immobilization. By coupling CAP-1 to magnetic beads, we demonstrate that we can target the amyloid structure of all protein aggregates present in human cerebrospinal fluid, isolate them for analysis and then characterize them using single-molecule fluorescence imaging and mass spectrometry. Amyloid precipitation enables unbiased determination of the molecular composition and structural features of the in vivo aggregates formed in neurodegenerative diseases. [Figure not available: see fulltext.]

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DO - 10.1038/s41557-022-00976-3

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VL - 14

SP - 1045

EP - 1053

JO - Nature Chemistry

JF - Nature Chemistry

IS - 9

ER -

Structure-specific amyloid precipitation in biofluids

Abstract

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