The annotation of GBA1 has been concealed by its protein-coding pseudogene GBAP1

Emil K. Gustavsson; Siddharth Sethi; Yujing Gao; Jonathan W. Brenton; Sonia García-Ruiz; David Zhang; Raquel Garza; Regina H. Reynolds; James R. Evans; Zhongbo Chen; Melissa Grant-Peters; Hannah Macpherson; Kylie Montgomery; Rhys Dore; Anna i. Wernick; Charles Arber; Selina Wray; Sonia Gandhi; Julian Esselborn; Cornelis Blauwendraat; Christopher H. Douse; Anita Adami; Diahann A. M. Atacho; Antonina Kouli; Annelies Quaegebeur; Roger A. Barker; Elisabet Englund; Frances Platt; Johan Jakobsson; Nicholas W. Wood; Henry Houlden; Harpreet Saini; Carla F. Bento; John Hardy; Mina Ryten

doi:10.1126/sciadv.adk1296

The annotation of GBA1 has been concealed by its protein-coding pseudogene GBAP1

Emil K. Gustavsson, Siddharth Sethi, Yujing Gao, Jonathan W. Brenton, Sonia García-Ruiz, David Zhang, Raquel Garza, Regina H. Reynolds, James R. Evans, Zhongbo Chen, Melissa Grant-Peters, Hannah Macpherson, Kylie Montgomery, Rhys Dore, Anna i. Wernick, Charles Arber, Selina Wray, Sonia Gandhi, Julian Esselborn, Cornelis BlauwendraatChristopher H. Douse, Anita Adami, Diahann A. M. Atacho, Antonina Kouli, Annelies Quaegebeur, Roger A. Barker, Elisabet Englund, Frances Platt, Johan Jakobsson, Nicholas W. Wood, Henry Houlden, Harpreet Saini, Carla F. Bento, John Hardy, Mina Ryten

Forskningsoutput: Tidskriftsbidrag › Artikel i vetenskaplig tidskrift › Peer review

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Mutations in GBA1 cause Gaucher disease and are the most important genetic risk factor for Parkinson’s disease. However, analysis of transcription at this locus is complicated by its highly homologous pseudogene, GBAP1. We show that >50% of short RNA-sequencing reads mapping to GBA1 also map to GBAP1. Thus, we used long-read RNA sequencing in the human brain, which allowed us to accurately quantify expression from both GBA1 and GBAP1. We discovered significant differences in expression compared to short-read data and identify currently unannotated transcripts of both GBA1 and GBAP1. These included protein-coding transcripts from both genes that were translated in human brain, but without the known lysosomal function—yet accounting for almost a third of transcription. Analyzing brain-specific cell types using long-read and single-nucleus RNA sequencing revealed region-specific variations in transcript expression. Overall, these findings suggest nonlysosomal roles for GBA1 and GBAP1 with implications for our understanding of the role of GBA1 in health and disease.

Originalspråk	engelska
Artikelnummer	eadk1296
Tidskrift	Science Advances
Volym	10
Nummer	26
DOI	https://doi.org/10.1126/sciadv.adk1296
Status	Published - 2024 juni 28

Ämnesklassifikation (UKÄ)

Medicinsk genetik och genomik (Här ingår: Genterapi)

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10.1126/sciadv.adk1296Licens: CC BY-NC

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Gustavsson, E. K., Sethi, S., Gao, Y., Brenton, J. W., García-Ruiz, S., Zhang, D., Garza, R., Reynolds, R. H., Evans, J. R., Chen, Z., Grant-Peters, M., Macpherson, H., Montgomery, K., Dore, R., Wernick, A. I., Arber, C., Wray, S., Gandhi, S., Esselborn, J., ... Ryten, M. (2024). The annotation of GBA1 has been concealed by its protein-coding pseudogene GBAP1. Science Advances, 10(26), Artikel eadk1296. https://doi.org/10.1126/sciadv.adk1296

@article{1bd86ba832fe42f2bfc1db96a69ef7ac,

title = "The annotation of GBA1 has been concealed by its protein-coding pseudogene GBAP1",

abstract = "Mutations in GBA1 cause Gaucher disease and are the most important genetic risk factor for Parkinson{\textquoteright}s disease. However, analysis of transcription at this locus is complicated by its highly homologous pseudogene, GBAP1. We show that >50% of short RNA-sequencing reads mapping to GBA1 also map to GBAP1. Thus, we used long-read RNA sequencing in the human brain, which allowed us to accurately quantify expression from both GBA1 and GBAP1. We discovered significant differences in expression compared to short-read data and identify currently unannotated transcripts of both GBA1 and GBAP1. These included protein-coding transcripts from both genes that were translated in human brain, but without the known lysosomal function—yet accounting for almost a third of transcription. Analyzing brain-specific cell types using long-read and single-nucleus RNA sequencing revealed region-specific variations in transcript expression. Overall, these findings suggest nonlysosomal roles for GBA1 and GBAP1 with implications for our understanding of the role of GBA1 in health and disease.",

author = "Gustavsson, {Emil K.} and Siddharth Sethi and Yujing Gao and Brenton, {Jonathan W.} and Sonia Garc{\'i}a-Ruiz and David Zhang and Raquel Garza and Reynolds, {Regina H.} and Evans, {James R.} and Zhongbo Chen and Melissa Grant-Peters and Hannah Macpherson and Kylie Montgomery and Rhys Dore and Wernick, {Anna i.} and Charles Arber and Selina Wray and Sonia Gandhi and Julian Esselborn and Cornelis Blauwendraat and Douse, {Christopher H.} and Anita Adami and Atacho, {Diahann A. M.} and Antonina Kouli and Annelies Quaegebeur and Barker, {Roger A.} and Elisabet Englund and Frances Platt and Johan Jakobsson and Wood, {Nicholas W.} and Henry Houlden and Harpreet Saini and Bento, {Carla F.} and John Hardy and Mina Ryten",

year = "2024",

month = jun,

day = "28",

doi = "10.1126/sciadv.adk1296",

language = "English",

volume = "10",

journal = "Science Advances",

issn = "2375-2548",

publisher = "American Association for the Advancement of Science (AAAS)",

number = "26",

}

Gustavsson, EK, Sethi, S, Gao, Y, Brenton, JW, García-Ruiz, S, Zhang, D, Garza, R, Reynolds, RH, Evans, JR, Chen, Z, Grant-Peters, M, Macpherson, H, Montgomery, K, Dore, R, Wernick, AI, Arber, C, Wray, S, Gandhi, S, Esselborn, J, Blauwendraat, C, Douse, CH , Adami, A, Atacho, DAM, Kouli, A, Quaegebeur, A, Barker, RA, Englund, E, Platt, F, Jakobsson, J, Wood, NW, Houlden, H, Saini, H, Bento, CF, Hardy, J & Ryten, M 2024, 'The annotation of GBA1 has been concealed by its protein-coding pseudogene GBAP1', Science Advances, vol. 10, nr. 26, eadk1296. https://doi.org/10.1126/sciadv.adk1296

TY - JOUR

T1 - The annotation of GBA1 has been concealed by its protein-coding pseudogene GBAP1

AU - Gustavsson, Emil K.

AU - Sethi, Siddharth

AU - Gao, Yujing

AU - Brenton, Jonathan W.

AU - García-Ruiz, Sonia

AU - Zhang, David

AU - Garza, Raquel

AU - Reynolds, Regina H.

AU - Evans, James R.

AU - Chen, Zhongbo

AU - Grant-Peters, Melissa

AU - Macpherson, Hannah

AU - Montgomery, Kylie

AU - Dore, Rhys

AU - Wernick, Anna i.

AU - Arber, Charles

AU - Wray, Selina

AU - Gandhi, Sonia

AU - Esselborn, Julian

AU - Blauwendraat, Cornelis

AU - Douse, Christopher H.

AU - Adami, Anita

AU - Atacho, Diahann A. M.

AU - Kouli, Antonina

AU - Quaegebeur, Annelies

AU - Barker, Roger A.

AU - Englund, Elisabet

AU - Platt, Frances

AU - Jakobsson, Johan

AU - Wood, Nicholas W.

AU - Houlden, Henry

AU - Saini, Harpreet

AU - Bento, Carla F.

AU - Hardy, John

AU - Ryten, Mina

PY - 2024/6/28

Y1 - 2024/6/28

N2 - Mutations in GBA1 cause Gaucher disease and are the most important genetic risk factor for Parkinson’s disease. However, analysis of transcription at this locus is complicated by its highly homologous pseudogene, GBAP1. We show that >50% of short RNA-sequencing reads mapping to GBA1 also map to GBAP1. Thus, we used long-read RNA sequencing in the human brain, which allowed us to accurately quantify expression from both GBA1 and GBAP1. We discovered significant differences in expression compared to short-read data and identify currently unannotated transcripts of both GBA1 and GBAP1. These included protein-coding transcripts from both genes that were translated in human brain, but without the known lysosomal function—yet accounting for almost a third of transcription. Analyzing brain-specific cell types using long-read and single-nucleus RNA sequencing revealed region-specific variations in transcript expression. Overall, these findings suggest nonlysosomal roles for GBA1 and GBAP1 with implications for our understanding of the role of GBA1 in health and disease.

AB - Mutations in GBA1 cause Gaucher disease and are the most important genetic risk factor for Parkinson’s disease. However, analysis of transcription at this locus is complicated by its highly homologous pseudogene, GBAP1. We show that >50% of short RNA-sequencing reads mapping to GBA1 also map to GBAP1. Thus, we used long-read RNA sequencing in the human brain, which allowed us to accurately quantify expression from both GBA1 and GBAP1. We discovered significant differences in expression compared to short-read data and identify currently unannotated transcripts of both GBA1 and GBAP1. These included protein-coding transcripts from both genes that were translated in human brain, but without the known lysosomal function—yet accounting for almost a third of transcription. Analyzing brain-specific cell types using long-read and single-nucleus RNA sequencing revealed region-specific variations in transcript expression. Overall, these findings suggest nonlysosomal roles for GBA1 and GBAP1 with implications for our understanding of the role of GBA1 in health and disease.

U2 - 10.1126/sciadv.adk1296

DO - 10.1126/sciadv.adk1296

M3 - Article

C2 - 38924406

SN - 2375-2548

VL - 10

JO - Science Advances

JF - Science Advances

IS - 26

M1 - eadk1296

ER -

The annotation of GBA1 has been concealed by its protein-coding pseudogene GBAP1

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