Expansion and mechanistic insights into de novo DEAF1 variants in DEAF1-associated neurodevelopmental disorders

Stacey R. McGee; Shivakumar Rajamanickam; Sandeep Adhikari; Oluwatosin C. Falayi; Theresa A. Wilson; Brian J. Shayota; Jessica A. Cooley Coleman; Cindy Skinner; Raymond C. Caylor; Roger E. Stevenson; Caio Robledo D’ Angioli Costa Quaio; Berenice Cunha Wilke; Jennifer M. Bain; Kwame Anyane-Yeboa; Kaitlyn Brown; John M. Greally; Emilia K. Bijlsma; Claudia A.L. Ruivenkamp; Keren Politi; Lydia A. Arbogast; Michael W. Collard; Jodi I. Huggenvik; Sarah H. Elsea; Philip J. Jensik

doi:10.1093/hmg/ddac200

Expansion and mechanistic insights into de novo DEAF1 variants in DEAF1-associated neurodevelopmental disorders

Stacey R. McGee, Shivakumar Rajamanickam, Sandeep Adhikari, Oluwatosin C. Falayi, Theresa A. Wilson, Brian J. Shayota, Jessica A. Cooley Coleman, Cindy Skinner, Raymond C. Caylor, Roger E. Stevenson, Caio Robledo D’ Angioli Costa Quaio, Berenice Cunha Wilke, Jennifer M. Bain, Kwame Anyane-Yeboa, Kaitlyn Brown, John M. Greally, Emilia K. Bijlsma, Claudia A.L. Ruivenkamp, Keren Politi, Lydia A. ArbogastMichael W. Collard, Jodi I. Huggenvik, Sarah H. Elsea, Philip J. Jensik

Genetics

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

Abstract

De novo deleterious and heritable biallelic mutations in the DNA binding domain (DBD) of the transcription factor deformed epidermal autoregulatory factor 1 (DEAF1) result in a phenotypic spectrum of disorders termed DEAF1-associated neurodevelopmental disorders (DAND). RNA-sequencing using hippocampal RNA from mice with conditional deletion of Deaf1 in the central nervous system indicate that loss of Deaf1 activity results in the altered expression of genes involved in neuronal function, dendritic spine maintenance, development, and activity, with reduced dendritic spines in hippocampal regions. Since DEAF1 is not a dosage-sensitive gene, we assessed the dominant negative activity of previously identified de novo variants and a heritable recessive DEAF1 variant on selected DEAF1-regulated genes in 2 different cell models. While no altered gene expression was observed in cells over-expressing the recessive heritable variant, the gene expression profiles of cells over-expressing de novo variants resulted in similar gene expression changes as observed in CRISPR-Cas9-mediated DEAF1-deleted cells. Altered expression of DEAF1-regulated genes was rescued by exogenous expression of WT-DEAF1 but not by de novo variants in cells lacking endogenous DEAF1. De novo heterozygous variants within the DBD of DEAF1 were identified in 10 individuals with a phenotypic spectrum including autism spectrum disorder, developmental delays, sleep disturbance, high pain tolerance, and mild dysmorphic features. Functional assays demonstrate these variants alter DEAF1 transcriptional activity. Taken together, this study expands the clinical phenotypic spectrum of individuals with DAND, furthers our understanding of potential roles of DEAF1 on neuronal function, and demonstrates dominant negative activity of identified de novo variants.

Original language	English (US)
Pages (from-to)	386-401
Number of pages	16
Journal	Human molecular genetics
Volume	32
Issue number	3
DOIs	https://doi.org/10.1093/hmg/ddac200
State	Published - Feb 1 2023

ASJC Scopus subject areas

Molecular Biology
Genetics
Genetics(clinical)

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McGee, S. R., Rajamanickam, S., Adhikari, S., Falayi, O. C., Wilson, T. A., Shayota, B. J., Cooley Coleman, J. A., Skinner, C., Caylor, R. C., Stevenson, R. E., D’ Angioli Costa Quaio, C. R., Wilke, B. C., Bain, J. M., Anyane-Yeboa, K., Brown, K., Greally, J. M., Bijlsma, E. K., Ruivenkamp, C. A. L., Politi, K., ... Jensik, P. J. (2023). Expansion and mechanistic insights into de novo DEAF1 variants in DEAF1-associated neurodevelopmental disorders. Human molecular genetics, 32(3), 386-401. https://doi.org/10.1093/hmg/ddac200

McGee, SR, Rajamanickam, S, Adhikari, S, Falayi, OC, Wilson, TA, Shayota, BJ, Cooley Coleman, JA, Skinner, C, Caylor, RC, Stevenson, RE, D’ Angioli Costa Quaio, CR, Wilke, BC, Bain, JM, Anyane-Yeboa, K, Brown, K, Greally, JM, Bijlsma, EK, Ruivenkamp, CAL, Politi, K, Arbogast, LA, Collard, MW, Huggenvik, JI, Elsea, SH & Jensik, PJ 2023, 'Expansion and mechanistic insights into de novo DEAF1 variants in DEAF1-associated neurodevelopmental disorders', Human molecular genetics, vol. 32, no. 3, pp. 386-401. https://doi.org/10.1093/hmg/ddac200

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title = "Expansion and mechanistic insights into de novo DEAF1 variants in DEAF1-associated neurodevelopmental disorders",

abstract = "De novo deleterious and heritable biallelic mutations in the DNA binding domain (DBD) of the transcription factor deformed epidermal autoregulatory factor 1 (DEAF1) result in a phenotypic spectrum of disorders termed DEAF1-associated neurodevelopmental disorders (DAND). RNA-sequencing using hippocampal RNA from mice with conditional deletion of Deaf1 in the central nervous system indicate that loss of Deaf1 activity results in the altered expression of genes involved in neuronal function, dendritic spine maintenance, development, and activity, with reduced dendritic spines in hippocampal regions. Since DEAF1 is not a dosage-sensitive gene, we assessed the dominant negative activity of previously identified de novo variants and a heritable recessive DEAF1 variant on selected DEAF1-regulated genes in 2 different cell models. While no altered gene expression was observed in cells over-expressing the recessive heritable variant, the gene expression profiles of cells over-expressing de novo variants resulted in similar gene expression changes as observed in CRISPR-Cas9-mediated DEAF1-deleted cells. Altered expression of DEAF1-regulated genes was rescued by exogenous expression of WT-DEAF1 but not by de novo variants in cells lacking endogenous DEAF1. De novo heterozygous variants within the DBD of DEAF1 were identified in 10 individuals with a phenotypic spectrum including autism spectrum disorder, developmental delays, sleep disturbance, high pain tolerance, and mild dysmorphic features. Functional assays demonstrate these variants alter DEAF1 transcriptional activity. Taken together, this study expands the clinical phenotypic spectrum of individuals with DAND, furthers our understanding of potential roles of DEAF1 on neuronal function, and demonstrates dominant negative activity of identified de novo variants.",

author = "McGee, {Stacey R.} and Shivakumar Rajamanickam and Sandeep Adhikari and Falayi, {Oluwatosin C.} and Wilson, {Theresa A.} and Shayota, {Brian J.} and {Cooley Coleman}, {Jessica A.} and Cindy Skinner and Caylor, {Raymond C.} and Stevenson, {Roger E.} and {D{\textquoteright} Angioli Costa Quaio}, {Caio Robledo} and Wilke, {Berenice Cunha} and Bain, {Jennifer M.} and Kwame Anyane-Yeboa and Kaitlyn Brown and Greally, {John M.} and Bijlsma, {Emilia K.} and Ruivenkamp, {Claudia A.L.} and Keren Politi and Arbogast, {Lydia A.} and Collard, {Michael W.} and Huggenvik, {Jodi I.} and Elsea, {Sarah H.} and Jensik, {Philip J.}",

year = "2023",

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doi = "10.1093/hmg/ddac200",

language = "English (US)",

volume = "32",

pages = "386--401",

journal = "Human molecular genetics",

issn = "0964-6906",

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T1 - Expansion and mechanistic insights into de novo DEAF1 variants in DEAF1-associated neurodevelopmental disorders

AU - McGee, Stacey R.

AU - Rajamanickam, Shivakumar

AU - Adhikari, Sandeep

AU - Falayi, Oluwatosin C.

AU - Wilson, Theresa A.

AU - Shayota, Brian J.

AU - Cooley Coleman, Jessica A.

AU - Skinner, Cindy

AU - Caylor, Raymond C.

AU - Stevenson, Roger E.

AU - D’ Angioli Costa Quaio, Caio Robledo

AU - Wilke, Berenice Cunha

AU - Bain, Jennifer M.

AU - Anyane-Yeboa, Kwame

AU - Brown, Kaitlyn

AU - Greally, John M.

AU - Bijlsma, Emilia K.

AU - Ruivenkamp, Claudia A.L.

AU - Politi, Keren

AU - Arbogast, Lydia A.

AU - Collard, Michael W.

AU - Huggenvik, Jodi I.

AU - Elsea, Sarah H.

AU - Jensik, Philip J.

PY - 2023/2/1

Y1 - 2023/2/1

N2 - De novo deleterious and heritable biallelic mutations in the DNA binding domain (DBD) of the transcription factor deformed epidermal autoregulatory factor 1 (DEAF1) result in a phenotypic spectrum of disorders termed DEAF1-associated neurodevelopmental disorders (DAND). RNA-sequencing using hippocampal RNA from mice with conditional deletion of Deaf1 in the central nervous system indicate that loss of Deaf1 activity results in the altered expression of genes involved in neuronal function, dendritic spine maintenance, development, and activity, with reduced dendritic spines in hippocampal regions. Since DEAF1 is not a dosage-sensitive gene, we assessed the dominant negative activity of previously identified de novo variants and a heritable recessive DEAF1 variant on selected DEAF1-regulated genes in 2 different cell models. While no altered gene expression was observed in cells over-expressing the recessive heritable variant, the gene expression profiles of cells over-expressing de novo variants resulted in similar gene expression changes as observed in CRISPR-Cas9-mediated DEAF1-deleted cells. Altered expression of DEAF1-regulated genes was rescued by exogenous expression of WT-DEAF1 but not by de novo variants in cells lacking endogenous DEAF1. De novo heterozygous variants within the DBD of DEAF1 were identified in 10 individuals with a phenotypic spectrum including autism spectrum disorder, developmental delays, sleep disturbance, high pain tolerance, and mild dysmorphic features. Functional assays demonstrate these variants alter DEAF1 transcriptional activity. Taken together, this study expands the clinical phenotypic spectrum of individuals with DAND, furthers our understanding of potential roles of DEAF1 on neuronal function, and demonstrates dominant negative activity of identified de novo variants.

AB - De novo deleterious and heritable biallelic mutations in the DNA binding domain (DBD) of the transcription factor deformed epidermal autoregulatory factor 1 (DEAF1) result in a phenotypic spectrum of disorders termed DEAF1-associated neurodevelopmental disorders (DAND). RNA-sequencing using hippocampal RNA from mice with conditional deletion of Deaf1 in the central nervous system indicate that loss of Deaf1 activity results in the altered expression of genes involved in neuronal function, dendritic spine maintenance, development, and activity, with reduced dendritic spines in hippocampal regions. Since DEAF1 is not a dosage-sensitive gene, we assessed the dominant negative activity of previously identified de novo variants and a heritable recessive DEAF1 variant on selected DEAF1-regulated genes in 2 different cell models. While no altered gene expression was observed in cells over-expressing the recessive heritable variant, the gene expression profiles of cells over-expressing de novo variants resulted in similar gene expression changes as observed in CRISPR-Cas9-mediated DEAF1-deleted cells. Altered expression of DEAF1-regulated genes was rescued by exogenous expression of WT-DEAF1 but not by de novo variants in cells lacking endogenous DEAF1. De novo heterozygous variants within the DBD of DEAF1 were identified in 10 individuals with a phenotypic spectrum including autism spectrum disorder, developmental delays, sleep disturbance, high pain tolerance, and mild dysmorphic features. Functional assays demonstrate these variants alter DEAF1 transcriptional activity. Taken together, this study expands the clinical phenotypic spectrum of individuals with DAND, furthers our understanding of potential roles of DEAF1 on neuronal function, and demonstrates dominant negative activity of identified de novo variants.

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ER -

Expansion and mechanistic insights into de novo DEAF1 variants in DEAF1-associated neurodevelopmental disorders

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