Bi-allelic PRMT9 loss-of-function variants cause a syndromic form of intellectual disability

Ariane Kröll-Hermi; Corinne Stoetzel; Christelle Etard; Levon Halabelian; Elise Schaefer; Sophie Scheidecker; Kimia Kahrizi; Jamali Payman; Véronique Geoffroy; Megana Prasad; Cathy Obringer; Laurie Ruch; Amandine Girard; Hong Zeng; Fengling Li; Damien Plassard; Céline Keime; Francesca Mattioli; Claire Feger; Amélie Piton; Atsushi Fujita; Naomichi Matsumoto; Matheus Augusto Araujo Castro; Kim Chong Ae; Lyse Ruaud; Jonathan Levy; Blandine Dozières; Anne-Claude Tabet; Ingrid M Wentzensen; Teresa Santiago-Sim; Roman Yusupov; Kristian Tveten; Marie Falkenberg Smeland; Ebba Alkhunaizi; Gina Cowing; Chumei Li; Saskia B Wortmann; René G Feichtinger; Johannes A Mayr; Herman Gonorazky; Gan Jing; Xiaodong Wang; Jia Wang; Tatjana Bierhals; Lev Grinstein; Theresia Herget; Anna Ruiz; Elisabeth Gabau; Antje Kampmeier; Olivier Kassel; Alma Kuechler; Konrad Platzer; Rami Abou Jamra; Audrey Woerner; Michaela Idleburg; Susanne Gerit Kircher; Franco Laccone; Barbara Golob; Borut Peterlin; Goran Čuturilo; Velibor Tasic; Caroline M Kolvenbach; Friedhelm Hildebrandt; Luiza L P Ramos; Fernando Kok; Cecilia Barbosa Buck; Ingrid M B H van de Laar; Stella A de Man; Elifcan Taşdelen; Abdullah Sezer; Afife Büke; Zehra Yavuz; Selim Selçuk Çomoğlu; Carrie Costin; Frédéric Tran Mau Them; Elodie Lacaze; Thomas Courtin; Delphine Héron; Boris Keren; Sandra Whalen; Joelle Roume; Yanzhong Yang; Mariëtte J V Hoffer; Arie van Haeringen; Hossein Najmabadi; Cheryl H Arrowsmith; Uwe Strähle; Hélène Dollfus; Jean Muller

doi:10.1016/j.ajhg.2025.10.014

Bi-allelic PRMT9 loss-of-function variants cause a syndromic form of intellectual disability

Ariane Kröll-Hermi
, Corinne Stoetzel
, Christelle Etard
, Levon Halabelian
, Elise Schaefer
, Sophie Scheidecker
, Kimia Kahrizi
, Jamali Payman
, Véronique Geoffroy
, Megana Prasad
, Cathy Obringer
, Laurie Ruch
, Amandine Girard
, Hong Zeng
, Fengling Li
, Damien Plassard
, Céline Keime
, Francesca Mattioli
, Claire Feger
, Amélie Piton

Atsushi Fujita, Naomichi Matsumoto, Matheus Augusto Araujo Castro, Kim Chong Ae, Lyse Ruaud, Jonathan Levy, Blandine Dozières, Anne-Claude Tabet, Ingrid M Wentzensen, Teresa Santiago-Sim, Roman Yusupov, Kristian Tveten, Marie Falkenberg Smeland, Ebba Alkhunaizi, Gina Cowing, Chumei Li, Saskia B Wortmann (Co-author), René G Feichtinger (Co-author), Johannes A Mayr (Co-author), Herman Gonorazky, Gan Jing, Xiaodong Wang, Jia Wang, Tatjana Bierhals, Lev Grinstein, Theresia Herget, Anna Ruiz, Elisabeth Gabau, Antje Kampmeier, Olivier Kassel, Alma Kuechler, Konrad Platzer, Rami Abou Jamra, Audrey Woerner, Michaela Idleburg, Susanne Gerit Kircher, Franco Laccone, Barbara Golob, Borut Peterlin, Goran Čuturilo, Velibor Tasic, Caroline M Kolvenbach, Friedhelm Hildebrandt, Luiza L P Ramos, Fernando Kok, Cecilia Barbosa Buck, Ingrid M B H van de Laar, Stella A de Man, Elifcan Taşdelen, Abdullah Sezer, Afife Büke, Zehra Yavuz, Selim Selçuk Çomoğlu, Carrie Costin, Frédéric Tran Mau Them, Elodie Lacaze, Thomas Courtin, Delphine Héron, Boris Keren, Sandra Whalen, Joelle Roume, Yanzhong Yang, Mariëtte J V Hoffer, Arie van Haeringen, Hossein Najmabadi, Cheryl H Arrowsmith, Uwe Strähle, Hélène Dollfus, Jean Muller

Department of Pediatrics

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

Abstract

Protein arginine methyltransferase 9 (PRMT9) is part of the PRMT family, and it is suspected to function in pathways relevant to neurodevelopment. It is thought to participate in alternative splicing through interactions with the splicing factor SF3B2 (SAP145). In this study, we report 26 families (35 individuals) with bi-allelic loss-of-function variants in PRMT9, implicating PRMT9 in an autosomal-recessive human disease. Individuals primarily present with a neurodevelopmental disorder characterized by global developmental delay, learning disabilities, mild to severe intellectual disability, autism spectrum disorder, epilepsy, and hypotonia. The mutation spectrum includes 26 different variants such as frameshifting indels, nonsense variants, missense variants, and two copy-number variants. Mapping of the disease-causing missense variants onto the crystal structure of PRMT9 revealed that several of the variants reside within the catalytically active module of PRMT9, likely impairing its methyltransferase activity and resulting in a loss of function. In skin fibroblasts derived from affected individuals, we observed reduced expression at the RNA and/or protein level and subsequent aberrant methylation activity. Moreover, transcriptomic analysis of fibroblasts from affected individuals indicated differential expression of genes related to intellectual disability, autism, and cilia, suggesting a role of PRMT9 during ciliogenesis. Under ciliogenesis conditions, the skin-derived fibroblasts exhibited anomalies in the length of primary cilia but normal amounts of cilia. In addition, a prmt9 knockout zebrafish model displayed abnormal social preference in adult animals. Altogether, our findings implicate bi-allelic PRMT9 loss-of-function variants as causal for neurodevelopmental disorders.

Original language	English
Journal	AMERICAN JOURNAL OF HUMAN GENETICS
DOIs	https://doi.org/10.1016/j.ajhg.2025.10.014
Publication status	E-pub ahead of print - 18 Nov 2025

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10.1016/j.ajhg.2025.10.014

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Kröll-Hermi, A., Stoetzel, C., Etard, C., Halabelian, L., Schaefer, E., Scheidecker, S., Kahrizi, K., Payman, J., Geoffroy, V., Prasad, M., Obringer, C., Ruch, L., Girard, A., Zeng, H., Li, F., Plassard, D., Keime, C., Mattioli, F., Feger, C., ... Muller, J. (2025). Bi-allelic PRMT9 loss-of-function variants cause a syndromic form of intellectual disability. AMERICAN JOURNAL OF HUMAN GENETICS Advance online publication. https://doi.org/10.1016/j.ajhg.2025.10.014

Kröll-Hermi, Ariane ; Stoetzel, Corinne ; Etard, Christelle et al. / Bi-allelic PRMT9 loss-of-function variants cause a syndromic form of intellectual disability. In: AMERICAN JOURNAL OF HUMAN GENETICS 2025.

@article{c7b24425f79b418e9cb4565f06f71394,

title = "Bi-allelic PRMT9 loss-of-function variants cause a syndromic form of intellectual disability",

abstract = "Protein arginine methyltransferase 9 (PRMT9) is part of the PRMT family, and it is suspected to function in pathways relevant to neurodevelopment. It is thought to participate in alternative splicing through interactions with the splicing factor SF3B2 (SAP145). In this study, we report 26 families (35 individuals) with bi-allelic loss-of-function variants in PRMT9, implicating PRMT9 in an autosomal-recessive human disease. Individuals primarily present with a neurodevelopmental disorder characterized by global developmental delay, learning disabilities, mild to severe intellectual disability, autism spectrum disorder, epilepsy, and hypotonia. The mutation spectrum includes 26 different variants such as frameshifting indels, nonsense variants, missense variants, and two copy-number variants. Mapping of the disease-causing missense variants onto the crystal structure of PRMT9 revealed that several of the variants reside within the catalytically active module of PRMT9, likely impairing its methyltransferase activity and resulting in a loss of function. In skin fibroblasts derived from affected individuals, we observed reduced expression at the RNA and/or protein level and subsequent aberrant methylation activity. Moreover, transcriptomic analysis of fibroblasts from affected individuals indicated differential expression of genes related to intellectual disability, autism, and cilia, suggesting a role of PRMT9 during ciliogenesis. Under ciliogenesis conditions, the skin-derived fibroblasts exhibited anomalies in the length of primary cilia but normal amounts of cilia. In addition, a prmt9 knockout zebrafish model displayed abnormal social preference in adult animals. Altogether, our findings implicate bi-allelic PRMT9 loss-of-function variants as causal for neurodevelopmental disorders.",

author = "Ariane Kr{\"o}ll-Hermi and Corinne Stoetzel and Christelle Etard and Levon Halabelian and Elise Schaefer and Sophie Scheidecker and Kimia Kahrizi and Jamali Payman and V{\'e}ronique Geoffroy and Megana Prasad and Cathy Obringer and Laurie Ruch and Amandine Girard and Hong Zeng and Fengling Li and Damien Plassard and C{\'e}line Keime and Francesca Mattioli and Claire Feger and Am{\'e}lie Piton and Atsushi Fujita and Naomichi Matsumoto and Castro, \{Matheus Augusto Araujo\} and Ae, \{Kim Chong\} and Lyse Ruaud and Jonathan Levy and Blandine Dozi{\`e}res and Anne-Claude Tabet and Wentzensen, \{Ingrid M\} and Teresa Santiago-Sim and Roman Yusupov and Kristian Tveten and Smeland, \{Marie Falkenberg\} and Ebba Alkhunaizi and Gina Cowing and Chumei Li and Wortmann, \{Saskia B\} and Feichtinger, \{Ren{\'e} G\} and Mayr, \{Johannes A\} and Herman Gonorazky and Gan Jing and Xiaodong Wang and Jia Wang and Tatjana Bierhals and Lev Grinstein and Theresia Herget and Anna Ruiz and Elisabeth Gabau and Antje Kampmeier and Olivier Kassel and Alma Kuechler and Konrad Platzer and Jamra, \{Rami Abou\} and Audrey Woerner and Michaela Idleburg and Kircher, \{Susanne Gerit\} and Franco Laccone and Barbara Golob and Borut Peterlin and Goran {\v C}uturilo and Velibor Tasic and Kolvenbach, \{Caroline M\} and Friedhelm Hildebrandt and Ramos, \{Luiza L P\} and Fernando Kok and Buck, \{Cecilia Barbosa\} and \{van de Laar\}, \{Ingrid M B H\} and \{de Man\}, \{Stella A\} and Elifcan Ta{\c s}delen and Abdullah Sezer and Afife B{\"u}ke and Zehra Yavuz and {\c C}omoğlu, \{Selim Sel{\c c}uk\} and Carrie Costin and \{Tran Mau Them\}, Fr{\'e}d{\'e}ric and Elodie Lacaze and Thomas Courtin and Delphine H{\'e}ron and Boris Keren and Sandra Whalen and Joelle Roume and Yanzhong Yang and Hoffer, \{Mari{\"e}tte J V\} and \{van Haeringen\}, Arie and Hossein Najmabadi and Arrowsmith, \{Cheryl H\} and Uwe Str{\"a}hle and H{\'e}l{\`e}ne Dollfus and Jean Muller",

note = "Wortmann, Mayr, Feichtinger: University Children{\textquoteright}s Hos- pital, Paracelsus Medical University (PMU), Salzburg, Austria",

year = "2025",

month = nov,

day = "18",

doi = "10.1016/j.ajhg.2025.10.014",

language = "English",

journal = "AMERICAN JOURNAL OF HUMAN GENETICS ",

issn = "0002-9297",

publisher = "Elsevier ",

}

Kröll-Hermi, A, Stoetzel, C, Etard, C, Halabelian, L, Schaefer, E, Scheidecker, S, Kahrizi, K, Payman, J, Geoffroy, V, Prasad, M, Obringer, C, Ruch, L, Girard, A, Zeng, H, Li, F, Plassard, D, Keime, C, Mattioli, F, Feger, C, Piton, A, Fujita, A, Matsumoto, N, Castro, MAA, Ae, KC, Ruaud, L, Levy, J, Dozières, B, Tabet, A-C, Wentzensen, IM, Santiago-Sim, T, Yusupov, R, Tveten, K, Smeland, MF, Alkhunaizi, E, Cowing, G, Li, C, Wortmann, SB , Feichtinger, RG , Mayr, JA, Gonorazky, H, Jing, G, Wang, X, Wang, J, Bierhals, T, Grinstein, L, Herget, T, Ruiz, A, Gabau, E, Kampmeier, A, Kassel, O, Kuechler, A, Platzer, K, Jamra, RA, Woerner, A, Idleburg, M, Kircher, SG, Laccone, F, Golob, B, Peterlin, B, Čuturilo, G, Tasic, V, Kolvenbach, CM, Hildebrandt, F, Ramos, LLP, Kok, F, Buck, CB, van de Laar, IMBH, de Man, SA, Taşdelen, E, Sezer, A, Büke, A, Yavuz, Z, Çomoğlu, SS, Costin, C, Tran Mau Them, F, Lacaze, E, Courtin, T, Héron, D, Keren, B, Whalen, S, Roume, J, Yang, Y, Hoffer, MJV, van Haeringen, A, Najmabadi, H, Arrowsmith, CH, Strähle, U, Dollfus, H & Muller, J 2025, 'Bi-allelic PRMT9 loss-of-function variants cause a syndromic form of intellectual disability', AMERICAN JOURNAL OF HUMAN GENETICS https://doi.org/10.1016/j.ajhg.2025.10.014

Bi-allelic PRMT9 loss-of-function variants cause a syndromic form of intellectual disability. / Kröll-Hermi, Ariane; Stoetzel, Corinne; Etard, Christelle et al.
In: AMERICAN JOURNAL OF HUMAN GENETICS , 18.11.2025.

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

TY - JOUR

T1 - Bi-allelic PRMT9 loss-of-function variants cause a syndromic form of intellectual disability

AU - Kröll-Hermi, Ariane

AU - Stoetzel, Corinne

AU - Etard, Christelle

AU - Halabelian, Levon

AU - Schaefer, Elise

AU - Scheidecker, Sophie

AU - Kahrizi, Kimia

AU - Payman, Jamali

AU - Geoffroy, Véronique

AU - Prasad, Megana

AU - Obringer, Cathy

AU - Ruch, Laurie

AU - Girard, Amandine

AU - Zeng, Hong

AU - Li, Fengling

AU - Plassard, Damien

AU - Keime, Céline

AU - Mattioli, Francesca

AU - Feger, Claire

AU - Piton, Amélie

AU - Fujita, Atsushi

AU - Matsumoto, Naomichi

AU - Castro, Matheus Augusto Araujo

AU - Ae, Kim Chong

AU - Ruaud, Lyse

AU - Levy, Jonathan

AU - Dozières, Blandine

AU - Tabet, Anne-Claude

AU - Wentzensen, Ingrid M

AU - Santiago-Sim, Teresa

AU - Yusupov, Roman

AU - Tveten, Kristian

AU - Smeland, Marie Falkenberg

AU - Alkhunaizi, Ebba

AU - Cowing, Gina

AU - Li, Chumei

AU - Wortmann, Saskia B

AU - Feichtinger, René G

AU - Mayr, Johannes A

AU - Gonorazky, Herman

AU - Jing, Gan

AU - Wang, Xiaodong

AU - Wang, Jia

AU - Bierhals, Tatjana

AU - Grinstein, Lev

AU - Herget, Theresia

AU - Ruiz, Anna

AU - Gabau, Elisabeth

AU - Kampmeier, Antje

AU - Kassel, Olivier

AU - Kuechler, Alma

AU - Platzer, Konrad

AU - Jamra, Rami Abou

AU - Woerner, Audrey

AU - Idleburg, Michaela

AU - Kircher, Susanne Gerit

AU - Laccone, Franco

AU - Golob, Barbara

AU - Peterlin, Borut

AU - Čuturilo, Goran

AU - Tasic, Velibor

AU - Kolvenbach, Caroline M

AU - Hildebrandt, Friedhelm

AU - Ramos, Luiza L P

AU - Kok, Fernando

AU - Buck, Cecilia Barbosa

AU - van de Laar, Ingrid M B H

AU - de Man, Stella A

AU - Taşdelen, Elifcan

AU - Sezer, Abdullah

AU - Büke, Afife

AU - Yavuz, Zehra

AU - Çomoğlu, Selim Selçuk

AU - Costin, Carrie

AU - Tran Mau Them, Frédéric

AU - Lacaze, Elodie

AU - Courtin, Thomas

AU - Héron, Delphine

AU - Keren, Boris

AU - Whalen, Sandra

AU - Roume, Joelle

AU - Yang, Yanzhong

AU - Hoffer, Mariëtte J V

AU - van Haeringen, Arie

AU - Najmabadi, Hossein

AU - Arrowsmith, Cheryl H

AU - Strähle, Uwe

AU - Dollfus, Hélène

AU - Muller, Jean

N1 - Wortmann, Mayr, Feichtinger: University Children’s Hos- pital, Paracelsus Medical University (PMU), Salzburg, Austria

PY - 2025/11/18

Y1 - 2025/11/18

N2 - Protein arginine methyltransferase 9 (PRMT9) is part of the PRMT family, and it is suspected to function in pathways relevant to neurodevelopment. It is thought to participate in alternative splicing through interactions with the splicing factor SF3B2 (SAP145). In this study, we report 26 families (35 individuals) with bi-allelic loss-of-function variants in PRMT9, implicating PRMT9 in an autosomal-recessive human disease. Individuals primarily present with a neurodevelopmental disorder characterized by global developmental delay, learning disabilities, mild to severe intellectual disability, autism spectrum disorder, epilepsy, and hypotonia. The mutation spectrum includes 26 different variants such as frameshifting indels, nonsense variants, missense variants, and two copy-number variants. Mapping of the disease-causing missense variants onto the crystal structure of PRMT9 revealed that several of the variants reside within the catalytically active module of PRMT9, likely impairing its methyltransferase activity and resulting in a loss of function. In skin fibroblasts derived from affected individuals, we observed reduced expression at the RNA and/or protein level and subsequent aberrant methylation activity. Moreover, transcriptomic analysis of fibroblasts from affected individuals indicated differential expression of genes related to intellectual disability, autism, and cilia, suggesting a role of PRMT9 during ciliogenesis. Under ciliogenesis conditions, the skin-derived fibroblasts exhibited anomalies in the length of primary cilia but normal amounts of cilia. In addition, a prmt9 knockout zebrafish model displayed abnormal social preference in adult animals. Altogether, our findings implicate bi-allelic PRMT9 loss-of-function variants as causal for neurodevelopmental disorders.

AB - Protein arginine methyltransferase 9 (PRMT9) is part of the PRMT family, and it is suspected to function in pathways relevant to neurodevelopment. It is thought to participate in alternative splicing through interactions with the splicing factor SF3B2 (SAP145). In this study, we report 26 families (35 individuals) with bi-allelic loss-of-function variants in PRMT9, implicating PRMT9 in an autosomal-recessive human disease. Individuals primarily present with a neurodevelopmental disorder characterized by global developmental delay, learning disabilities, mild to severe intellectual disability, autism spectrum disorder, epilepsy, and hypotonia. The mutation spectrum includes 26 different variants such as frameshifting indels, nonsense variants, missense variants, and two copy-number variants. Mapping of the disease-causing missense variants onto the crystal structure of PRMT9 revealed that several of the variants reside within the catalytically active module of PRMT9, likely impairing its methyltransferase activity and resulting in a loss of function. In skin fibroblasts derived from affected individuals, we observed reduced expression at the RNA and/or protein level and subsequent aberrant methylation activity. Moreover, transcriptomic analysis of fibroblasts from affected individuals indicated differential expression of genes related to intellectual disability, autism, and cilia, suggesting a role of PRMT9 during ciliogenesis. Under ciliogenesis conditions, the skin-derived fibroblasts exhibited anomalies in the length of primary cilia but normal amounts of cilia. In addition, a prmt9 knockout zebrafish model displayed abnormal social preference in adult animals. Altogether, our findings implicate bi-allelic PRMT9 loss-of-function variants as causal for neurodevelopmental disorders.

U2 - 10.1016/j.ajhg.2025.10.014

DO - 10.1016/j.ajhg.2025.10.014

M3 - Original Article

C2 - 41260215

SN - 0002-9297

JO - AMERICAN JOURNAL OF HUMAN GENETICS

JF - AMERICAN JOURNAL OF HUMAN GENETICS

ER -

Kröll-Hermi A, Stoetzel C, Etard C, Halabelian L, Schaefer E, Scheidecker S et al. Bi-allelic PRMT9 loss-of-function variants cause a syndromic form of intellectual disability. AMERICAN JOURNAL OF HUMAN GENETICS . 2025 Nov 18. Epub 2025 Nov 18. doi: 10.1016/j.ajhg.2025.10.014

Bi-allelic PRMT9 loss-of-function variants cause a syndromic form of intellectual disability

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