A novel GFAP frameshift variant identified in a family with optico-retinal dysplasia and vision impairment

Menachem V K Sarusie; Cecilia Rönnbäck; Cathrine Jespersgaard; Sif Baungaard; Yeasmeen Ali; Line Kessel; Søren T Christensen; Karen Brøndum-Nielsen; Kjeld Møllgård; Thomas Rosenberg; Lars A Larsen; Karen Grønskov

doi:10.1093/hmg/ddae134

A novel GFAP frameshift variant identified in a family with optico-retinal dysplasia and vision impairment

Menachem V K Sarusie, Cecilia Rönnbäck, Cathrine Jespersgaard, Sif Baungaard, Yeasmeen Ali, Line Kessel, Søren T Christensen, Karen Brøndum-Nielsen, Kjeld Møllgård, Thomas Rosenberg, Lars A Larsen, Karen Grønskov^*

^*Corresponding author for this work

1 Citation (Scopus)

Abstract

Gain-of-function variants in GFAP leads to protein aggregation and is the cause of the severe neurodegenerative disorder Alexander Disease (AxD), while loss of GFAP function has been considered benign. Here, we investigated a six-generation family, where multiple individuals presented with gliosis of the optic nerve head and visual impairment. Whole genome sequencing (WGS) revealed a frameshift variant in GFAP (c.928dup, p.(Met310Asnfs*113)) segregating with disease. Analysis of human embryonic tissues revealed strong expression of GFAP in retinal neural progenitors. A zebrafish model verified that c.928dup does not result in extensive GFAP protein aggregation and zebrafish gfap loss-of-function mutants showed vision impairment and retinal dysplasia, characterized by a significant loss of Müller glia cells and photoreceptor cells. Our findings show how different mutational mechanisms can cause diverging phenotypes and reveal a novel function of GFAP in vertebrate eye development.

Original language	English
Journal	Human Molecular Genetics
Volume	33
Issue number	24
Pages (from-to)	2145-2158
Number of pages	14
ISSN	0964-6906
DOIs	https://doi.org/10.1093/hmg/ddae134
Publication status	Published - 6 Dec 2024

Keywords

Alexander's disease
GFAP
Hereditary
optico-retinal dysplasia

Access to Document

10.1093/hmg/ddae134

Cite this

Sarusie, M. V. K., Rönnbäck, C., Jespersgaard, C., Baungaard, S., Ali, Y., Kessel, L., Christensen, S. T., Brøndum-Nielsen, K., Møllgård, K., Rosenberg, T., Larsen, L. A., & Grønskov, K. (2024). A novel GFAP frameshift variant identified in a family with optico-retinal dysplasia and vision impairment. Human Molecular Genetics, 33(24), 2145-2158. https://doi.org/10.1093/hmg/ddae134

Sarusie, MVK, Rönnbäck, C, Jespersgaard, C, Baungaard, S, Ali, Y, Kessel, L, Christensen, ST, Brøndum-Nielsen, K, Møllgård, K, Rosenberg, T, Larsen, LA & Grønskov, K 2024, 'A novel GFAP frameshift variant identified in a family with optico-retinal dysplasia and vision impairment', Human Molecular Genetics, vol. 33, no. 24, pp. 2145-2158. https://doi.org/10.1093/hmg/ddae134

@article{267d9e4ec6a945e4afdbcb48e929612c,

title = "A novel GFAP frameshift variant identified in a family with optico-retinal dysplasia and vision impairment",

abstract = "Gain-of-function variants in GFAP leads to protein aggregation and is the cause of the severe neurodegenerative disorder Alexander Disease (AxD), while loss of GFAP function has been considered benign. Here, we investigated a six-generation family, where multiple individuals presented with gliosis of the optic nerve head and visual impairment. Whole genome sequencing (WGS) revealed a frameshift variant in GFAP (c.928dup, p.(Met310Asnfs*113)) segregating with disease. Analysis of human embryonic tissues revealed strong expression of GFAP in retinal neural progenitors. A zebrafish model verified that c.928dup does not result in extensive GFAP protein aggregation and zebrafish gfap loss-of-function mutants showed vision impairment and retinal dysplasia, characterized by a significant loss of M{\"u}ller glia cells and photoreceptor cells. Our findings show how different mutational mechanisms can cause diverging phenotypes and reveal a novel function of GFAP in vertebrate eye development.",

keywords = "Alexander's disease, GFAP, Hereditary, optico-retinal dysplasia",

author = "Sarusie, \{Menachem V K\} and Cecilia R{\"o}nnb{\"a}ck and Cathrine Jespersgaard and Sif Baungaard and Yeasmeen Ali and Line Kessel and Christensen, \{S{\o}ren T\} and Karen Br{\o}ndum-Nielsen and Kjeld M{\o}llg{\aa}rd and Thomas Rosenberg and Larsen, \{Lars A\} and Karen Gr{\o}nskov",

year = "2024",

month = dec,

day = "6",

doi = "10.1093/hmg/ddae134",

language = "English",

volume = "33",

pages = "2145--2158",

journal = "Human Molecular Genetics",

issn = "0964-6906",

publisher = "Oxford University Press",

number = "24",

}

TY - JOUR

T1 - A novel GFAP frameshift variant identified in a family with optico-retinal dysplasia and vision impairment

AU - Sarusie, Menachem V K

AU - Rönnbäck, Cecilia

AU - Jespersgaard, Cathrine

AU - Baungaard, Sif

AU - Ali, Yeasmeen

AU - Kessel, Line

AU - Christensen, Søren T

AU - Brøndum-Nielsen, Karen

AU - Møllgård, Kjeld

AU - Rosenberg, Thomas

AU - Larsen, Lars A

AU - Grønskov, Karen

PY - 2024/12/6

Y1 - 2024/12/6

N2 - Gain-of-function variants in GFAP leads to protein aggregation and is the cause of the severe neurodegenerative disorder Alexander Disease (AxD), while loss of GFAP function has been considered benign. Here, we investigated a six-generation family, where multiple individuals presented with gliosis of the optic nerve head and visual impairment. Whole genome sequencing (WGS) revealed a frameshift variant in GFAP (c.928dup, p.(Met310Asnfs*113)) segregating with disease. Analysis of human embryonic tissues revealed strong expression of GFAP in retinal neural progenitors. A zebrafish model verified that c.928dup does not result in extensive GFAP protein aggregation and zebrafish gfap loss-of-function mutants showed vision impairment and retinal dysplasia, characterized by a significant loss of Müller glia cells and photoreceptor cells. Our findings show how different mutational mechanisms can cause diverging phenotypes and reveal a novel function of GFAP in vertebrate eye development.

AB - Gain-of-function variants in GFAP leads to protein aggregation and is the cause of the severe neurodegenerative disorder Alexander Disease (AxD), while loss of GFAP function has been considered benign. Here, we investigated a six-generation family, where multiple individuals presented with gliosis of the optic nerve head and visual impairment. Whole genome sequencing (WGS) revealed a frameshift variant in GFAP (c.928dup, p.(Met310Asnfs*113)) segregating with disease. Analysis of human embryonic tissues revealed strong expression of GFAP in retinal neural progenitors. A zebrafish model verified that c.928dup does not result in extensive GFAP protein aggregation and zebrafish gfap loss-of-function mutants showed vision impairment and retinal dysplasia, characterized by a significant loss of Müller glia cells and photoreceptor cells. Our findings show how different mutational mechanisms can cause diverging phenotypes and reveal a novel function of GFAP in vertebrate eye development.

KW - Alexander's disease

KW - GFAP

KW - Hereditary

KW - optico-retinal dysplasia

UR - https://www.scopus.com/pages/publications/85212457548

U2 - 10.1093/hmg/ddae134

DO - 10.1093/hmg/ddae134

M3 - Journal article

C2 - 39471354

SN - 0964-6906

VL - 33

SP - 2145

EP - 2158

JO - Human Molecular Genetics

JF - Human Molecular Genetics

IS - 24

ER -

A novel GFAP frameshift variant identified in a family with optico-retinal dysplasia and vision impairment

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this