Genetic variation across RNA metabolism and cell death gene networks is implicated in the semantic variant of primary progressive aphasia

Luke W. Bonham; Natasha Z. R. Steele; Celeste M. Karch; Iris Broce; Ethan G. Geier; Natalie L. Wen; Parastoo Momeni; John Hardy; Zachary A. Miller; Maria Luisa Gorno-Tempini; Christopher P. Hess; Patrick Lewis; Bruce L. Miller; William W. Seeley; Claudia Manzoni; Rahul S. Desikan; Sergio E. Baranzini; Raffaele Ferrari; Jennifer S. Yokoyama; International FTD-Genomics Consortium (IFGC)

doi:10.1038/s41598-019-46415-1

Genetic variation across RNA metabolism and cell death gene networks is implicated in the semantic variant of primary progressive aphasia

Luke W. Bonham, Natasha Z. R. Steele, Celeste M. Karch, Iris Broce, Ethan G. Geier, Natalie L. Wen, Parastoo Momeni, John Hardy, Zachary A. Miller, Maria Luisa Gorno-Tempini, Christopher P. Hess, Patrick Lewis, Bruce L. Miller, William W. Seeley, Claudia Manzoni, Rahul S. Desikan, Sergio E. Baranzini, Raffaele Ferrari, Jennifer S. Yokoyama, International FTD-Genomics Consortium (IFGC)

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

Abstract

The semantic variant of primary progressive aphasia (svPPA) is a clinical syndrome characterized by neurodegeneration and progressive loss of semantic knowledge. Unlike many other forms of frontotemporal lobar degeneration (FTLD), svPPA has a highly consistent underlying pathology composed of TDP-43 (a regulator of RNA and DNA transcription metabolism). Previous genetic studies of svPPA are limited by small sample sizes and a paucity of common risk variants. Despite this, svPPA’s relatively homogenous clinicopathologic phenotype makes it an ideal investigative model to examine genetic processes that may drive neurodegenerative disease. In this study, we used GWAS metadata, tissue samples from pathologically confirmed frontotemporal lobar degeneration, and in silico techniques to identify and characterize protein interaction networks associated with svPPA risk. We identified 64 svPPA risk genes that interact at the protein level. The protein pathways represented in this svPPA gene network are critical regulators of RNA metabolism and cell death, such as SMAD proteins and NOTCH1. Many of the genes in this network are involved in TDP-43 metabolism. Contrary to the conventional notion that svPPA is a clinical syndrome with few genetic risk factors, our analyses show that svPPA risk is complex and polygenic in nature. Risk for svPPA is likely driven by multiple common variants in genes interacting with TDP-43, along with cell death,x` working in combination to promote neurodegeneration.

Original language	English
Article number	10854
Journal	Scientific Reports
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s41598-019-46415-1
Publication status	Published - 1 Dec 2019

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Bonham, L. W., Steele, N. Z. R., Karch, C. M., Broce, I., Geier, E. G., Wen, N. L., Momeni, P., Hardy, J., Miller, Z. A., Gorno-Tempini, M. L., Hess, C. P., Lewis, P., Miller, B. L., Seeley, W. W., Manzoni, C., Desikan, R. S., Baranzini, S. E., Ferrari, R., Yokoyama, J. S., & International FTD-Genomics Consortium (IFGC) (2019). Genetic variation across RNA metabolism and cell death gene networks is implicated in the semantic variant of primary progressive aphasia. Scientific Reports, 9(1), [10854]. https://doi.org/10.1038/s41598-019-46415-1

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title = "Genetic variation across RNA metabolism and cell death gene networks is implicated in the semantic variant of primary progressive aphasia",

abstract = "The semantic variant of primary progressive aphasia (svPPA) is a clinical syndrome characterized by neurodegeneration and progressive loss of semantic knowledge. Unlike many other forms of frontotemporal lobar degeneration (FTLD), svPPA has a highly consistent underlying pathology composed of TDP-43 (a regulator of RNA and DNA transcription metabolism). Previous genetic studies of svPPA are limited by small sample sizes and a paucity of common risk variants. Despite this, svPPA{\textquoteright}s relatively homogenous clinicopathologic phenotype makes it an ideal investigative model to examine genetic processes that may drive neurodegenerative disease. In this study, we used GWAS metadata, tissue samples from pathologically confirmed frontotemporal lobar degeneration, and in silico techniques to identify and characterize protein interaction networks associated with svPPA risk. We identified 64 svPPA risk genes that interact at the protein level. The protein pathways represented in this svPPA gene network are critical regulators of RNA metabolism and cell death, such as SMAD proteins and NOTCH1. Many of the genes in this network are involved in TDP-43 metabolism. Contrary to the conventional notion that svPPA is a clinical syndrome with few genetic risk factors, our analyses show that svPPA risk is complex and polygenic in nature. Risk for svPPA is likely driven by multiple common variants in genes interacting with TDP-43, along with cell death,x` working in combination to promote neurodegeneration.",

author = "Bonham, {Luke W.} and Steele, {Natasha Z. R.} and Karch, {Celeste M.} and Iris Broce and Geier, {Ethan G.} and Wen, {Natalie L.} and Parastoo Momeni and John Hardy and Miller, {Zachary A.} and Gorno-Tempini, {Maria Luisa} and Hess, {Christopher P.} and Patrick Lewis and Miller, {Bruce L.} and Seeley, {William W.} and Claudia Manzoni and Desikan, {Rahul S.} and Baranzini, {Sergio E.} and Raffaele Ferrari and Yokoyama, {Jennifer S.} and Hernandez, {D. G.} and Nalls, {M. A.} and Rohrer, {J. D.} and A. Ramasamy and Kwok, {J. B. J.} and C. Dobson-Stone and Schofield, {P. R.} and Halliday, {G. M.} and Hodges, {J. R.} and O. Piguet and L. Bartley and E. Thompson and E. Haan and G. Giaccone and Fox, {N. C.} and P. Rizzu and P. Heutink and {van Swieten}, {J. C.} and Dopper, {E. G. P.} and Pijnenburg, {Y. A. L.} and P. Scheltens and P. Sorrentino and {International FTD-Genomics Consortium (IFGC)} and G. Giaccone and Fox, {N. C.} and P. Rizzu and P. Heutink and {van Swieten}, {J. C.} and Dopper, {E. G. P.} and Pijnenburg, {Y. A. L.} and P. Scheltens and P. Sorrentino and Mark Kristiansen and Huei-Hsin Chiang and Caroline Graff and F. Pasquier and Adeline Rollin and Vincent Deramecourt and Thibaud Lebouvier and Dimitrios Kapogiannis and Luigi Ferrucci and S. Pickering-Brown and Singleton, {Andrew B.}",

year = "2019",

month = dec,

day = "1",

doi = "10.1038/s41598-019-46415-1",

language = "English",

volume = "9",

journal = "Scientific Reports",

issn = "2045-2322",

publisher = "Nature Publishing Group",

number = "1",

}

Bonham, LW, Steele, NZR, Karch, CM, Broce, I, Geier, EG, Wen, NL, Momeni, P, Hardy, J, Miller, ZA, Gorno-Tempini, ML, Hess, CP, Lewis, P, Miller, BL, Seeley, WW, Manzoni, C, Desikan, RS, Baranzini, SE, Ferrari, R, Yokoyama, JS & International FTD-Genomics Consortium (IFGC) 2019, 'Genetic variation across RNA metabolism and cell death gene networks is implicated in the semantic variant of primary progressive aphasia', Scientific Reports, vol. 9, no. 1, 10854. https://doi.org/10.1038/s41598-019-46415-1

TY - JOUR

T1 - Genetic variation across RNA metabolism and cell death gene networks is implicated in the semantic variant of primary progressive aphasia

AU - Bonham, Luke W.

AU - Steele, Natasha Z. R.

AU - Karch, Celeste M.

AU - Broce, Iris

AU - Geier, Ethan G.

AU - Wen, Natalie L.

AU - Momeni, Parastoo

AU - Hardy, John

AU - Miller, Zachary A.

AU - Gorno-Tempini, Maria Luisa

AU - Hess, Christopher P.

AU - Lewis, Patrick

AU - Miller, Bruce L.

AU - Seeley, William W.

AU - Manzoni, Claudia

AU - Desikan, Rahul S.

AU - Baranzini, Sergio E.

AU - Ferrari, Raffaele

AU - Yokoyama, Jennifer S.

AU - Hernandez, D. G.

AU - Nalls, M. A.

AU - Rohrer, J. D.

AU - Ramasamy, A.

AU - Kwok, J. B. J.

AU - Dobson-Stone, C.

AU - Schofield, P. R.

AU - Halliday, G. M.

AU - Hodges, J. R.

AU - Piguet, O.

AU - Bartley, L.

AU - Thompson, E.

AU - Haan, E.

AU - Giaccone, G.

AU - Fox, N. C.

AU - Rizzu, P.

AU - Heutink, P.

AU - van Swieten, J. C.

AU - Dopper, E. G. P.

AU - Pijnenburg, Y. A. L.

AU - Scheltens, P.

AU - Sorrentino, P.

AU - International FTD-Genomics Consortium (IFGC)

AU - Giaccone, G.

AU - Fox, N. C.

AU - Rizzu, P.

AU - Heutink, P.

AU - van Swieten, J. C.

AU - Dopper, E. G. P.

AU - Pijnenburg, Y. A. L.

AU - Scheltens, P.

AU - Sorrentino, P.

AU - Kristiansen, Mark

AU - Chiang, Huei-Hsin

AU - Graff, Caroline

AU - Pasquier, F.

AU - Rollin, Adeline

AU - Deramecourt, Vincent

AU - Lebouvier, Thibaud

AU - Kapogiannis, Dimitrios

AU - Ferrucci, Luigi

AU - Pickering-Brown, S.

AU - Singleton, Andrew B.

PY - 2019/12/1

Y1 - 2019/12/1

N2 - The semantic variant of primary progressive aphasia (svPPA) is a clinical syndrome characterized by neurodegeneration and progressive loss of semantic knowledge. Unlike many other forms of frontotemporal lobar degeneration (FTLD), svPPA has a highly consistent underlying pathology composed of TDP-43 (a regulator of RNA and DNA transcription metabolism). Previous genetic studies of svPPA are limited by small sample sizes and a paucity of common risk variants. Despite this, svPPA’s relatively homogenous clinicopathologic phenotype makes it an ideal investigative model to examine genetic processes that may drive neurodegenerative disease. In this study, we used GWAS metadata, tissue samples from pathologically confirmed frontotemporal lobar degeneration, and in silico techniques to identify and characterize protein interaction networks associated with svPPA risk. We identified 64 svPPA risk genes that interact at the protein level. The protein pathways represented in this svPPA gene network are critical regulators of RNA metabolism and cell death, such as SMAD proteins and NOTCH1. Many of the genes in this network are involved in TDP-43 metabolism. Contrary to the conventional notion that svPPA is a clinical syndrome with few genetic risk factors, our analyses show that svPPA risk is complex and polygenic in nature. Risk for svPPA is likely driven by multiple common variants in genes interacting with TDP-43, along with cell death,x` working in combination to promote neurodegeneration.

AB - The semantic variant of primary progressive aphasia (svPPA) is a clinical syndrome characterized by neurodegeneration and progressive loss of semantic knowledge. Unlike many other forms of frontotemporal lobar degeneration (FTLD), svPPA has a highly consistent underlying pathology composed of TDP-43 (a regulator of RNA and DNA transcription metabolism). Previous genetic studies of svPPA are limited by small sample sizes and a paucity of common risk variants. Despite this, svPPA’s relatively homogenous clinicopathologic phenotype makes it an ideal investigative model to examine genetic processes that may drive neurodegenerative disease. In this study, we used GWAS metadata, tissue samples from pathologically confirmed frontotemporal lobar degeneration, and in silico techniques to identify and characterize protein interaction networks associated with svPPA risk. We identified 64 svPPA risk genes that interact at the protein level. The protein pathways represented in this svPPA gene network are critical regulators of RNA metabolism and cell death, such as SMAD proteins and NOTCH1. Many of the genes in this network are involved in TDP-43 metabolism. Contrary to the conventional notion that svPPA is a clinical syndrome with few genetic risk factors, our analyses show that svPPA risk is complex and polygenic in nature. Risk for svPPA is likely driven by multiple common variants in genes interacting with TDP-43, along with cell death,x` working in combination to promote neurodegeneration.

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UR - https://www.ncbi.nlm.nih.gov/pubmed/31350420

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DO - 10.1038/s41598-019-46415-1

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VL - 9

JO - Scientific Reports

JF - Scientific Reports

SN - 2045-2322

IS - 1

M1 - 10854

ER -

Genetic variation across RNA metabolism and cell death gene networks is implicated in the semantic variant of primary progressive aphasia

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