Loss of DOT1L function disrupts neuronal transcription, animal behavior, and leads to a novel neurodevelopmental disorder

Marissa J Maroni; Melissa Barton; Katherine Lynch; Ashish R Deshwar; Philip Campbell; Josephine Millard; Rachel Lee; Annastelle Cohen; Alekh Paranjapye; Víctor Faundes; Gabriela M Repetto; Caoimhe McKenna; Amelle L Shillington; Chanika Phornphutkul; Grazia Ms Mancini; Rachel Schot; Tahsin Stefan Barakat; Christopher M Richmond; Julie Lauzon; Ahmed Ibrahim Elsayed Ibrahim; Daniel Natera-de Benito; Carlos Ortez; Berta Estevez-Arias; François Lecoquierre; Kévin Cassinari; Anne-Marie Guerrot; Jonathan Levy; Xenia Latypova; Alain Verloes; A Micheil Innes; Siddharth Banka; Katharina Vill; Maureen Jacob; Michael Kruer; Peter Skidmore; Carolina I Galaz-Montoya; Somayeh Bakhtiari; Jessica L Mester; Michael Granato; Karim-Jean Armache; Gregory Costain; Erica Korb

doi:10.1101/2024.10.31.24314716

Loss of DOT1L function disrupts neuronal transcription, animal behavior, and leads to a novel neurodevelopmental disorder

Marissa J Maroni, Melissa Barton, Katherine Lynch, Ashish R Deshwar, Philip Campbell, Josephine Millard, Rachel Lee, Annastelle Cohen, Alekh Paranjapye, Víctor Faundes, Gabriela M Repetto, Caoimhe McKenna, Amelle L Shillington, Chanika Phornphutkul, Grazia Ms Mancini, Rachel Schot, Tahsin Stefan Barakat, Christopher M Richmond, Julie Lauzon, Ahmed Ibrahim Elsayed IbrahimDaniel Natera-de Benito, Carlos Ortez, Berta Estevez-Arias, François Lecoquierre, Kévin Cassinari, Anne-Marie Guerrot, Jonathan Levy, Xenia Latypova, Alain Verloes, A Micheil Innes, Siddharth Banka, Katharina Vill, Maureen Jacob, Michael Kruer, Peter Skidmore, Carolina I Galaz-Montoya, Somayeh Bakhtiari, Jessica L Mester, Michael Granato, Karim-Jean Armache, Gregory Costain, Erica Korb

Division of Evolution, Infection and Genomics

Research output: Preprint/Working paper › Preprint

Abstract

Individuals with monoallelic pathogenic variants in the histone lysine methyltransferase DOT1L display global developmental delay and varying congenital anomalies. However, the impact of monoallelic loss of DOT1L remains unclear. Here, we present a largely female cohort of 11 individuals with DOT1L variants with developmental delays and dysmorphic facial features. We found that DOT1L variants include missense variants clustered in the catalytic domain, frameshift, and stop-gain variants. We demonstrate that specific variants cause loss of methyltransferase activity and therefore sought to define the effects of decreased DOT1L function. Using RNA-sequencing of cultured neurons and single nucleus RNA-sequencing of mouse cortical tissue, we found that partial Dot1l depletion causes sex-specific transcriptional responses and disrupts transcription of synaptic genes. Further, Dot1l loss alters neuron branching and expression of synaptic proteins. Lastly using zebrafish and mouse models, we found behavioral disruptions that include sex-specific deficits in mice. Overall, we define how DOT1L loss leads to neurological dysfunction by demonstrating that partial Dot1l loss impacts transcription, neuron morphology, and behavior across multiple models and systems.

Original language	English
Publisher	Cold Spring Harbor Laboratory Press
DOIs	https://doi.org/10.1101/2024.10.31.24314716
Publication status	Published - 2 Nov 2024

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Name	medRxiv
Publisher	Cold Spring Harbor Laboratory Press

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10.1101/2024.10.31.24314716Licence: CC BY-NC-ND

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Maroni, M. J., Barton, M., Lynch, K., Deshwar, A. R., Campbell, P., Millard, J., Lee, R., Cohen, A., Paranjapye, A., Faundes, V., Repetto, G. M., McKenna, C., Shillington, A. L., Phornphutkul, C., Mancini, G. M., Schot, R., Barakat, T. S., Richmond, C. M., Lauzon, J., ... Korb, E. (2024). Loss of DOT1L function disrupts neuronal transcription, animal behavior, and leads to a novel neurodevelopmental disorder. (medRxiv). Cold Spring Harbor Laboratory Press. https://doi.org/10.1101/2024.10.31.24314716

@techreport{c618f189dffd4159846dad14733a8075,

title = "Loss of DOT1L function disrupts neuronal transcription, animal behavior, and leads to a novel neurodevelopmental disorder",

abstract = "Individuals with monoallelic pathogenic variants in the histone lysine methyltransferase DOT1L display global developmental delay and varying congenital anomalies. However, the impact of monoallelic loss of DOT1L remains unclear. Here, we present a largely female cohort of 11 individuals with DOT1L variants with developmental delays and dysmorphic facial features. We found that DOT1L variants include missense variants clustered in the catalytic domain, frameshift, and stop-gain variants. We demonstrate that specific variants cause loss of methyltransferase activity and therefore sought to define the effects of decreased DOT1L function. Using RNA-sequencing of cultured neurons and single nucleus RNA-sequencing of mouse cortical tissue, we found that partial Dot1l depletion causes sex-specific transcriptional responses and disrupts transcription of synaptic genes. Further, Dot1l loss alters neuron branching and expression of synaptic proteins. Lastly using zebrafish and mouse models, we found behavioral disruptions that include sex-specific deficits in mice. Overall, we define how DOT1L loss leads to neurological dysfunction by demonstrating that partial Dot1l loss impacts transcription, neuron morphology, and behavior across multiple models and systems. ",

author = "Maroni, {Marissa J} and Melissa Barton and Katherine Lynch and Deshwar, {Ashish R} and Philip Campbell and Josephine Millard and Rachel Lee and Annastelle Cohen and Alekh Paranjapye and V{\'i}ctor Faundes and Repetto, {Gabriela M} and Caoimhe McKenna and Shillington, {Amelle L} and Chanika Phornphutkul and Mancini, {Grazia Ms} and Rachel Schot and Barakat, {Tahsin Stefan} and Richmond, {Christopher M} and Julie Lauzon and {Elsayed Ibrahim}, {Ahmed Ibrahim} and Benito, {Daniel Natera-de} and Carlos Ortez and Berta Estevez-Arias and Fran{\c c}ois Lecoquierre and K{\'e}vin Cassinari and Anne-Marie Guerrot and Jonathan Levy and Xenia Latypova and Alain Verloes and Innes, {A Micheil} and Siddharth Banka and Katharina Vill and Maureen Jacob and Michael Kruer and Peter Skidmore and Galaz-Montoya, {Carolina I} and Somayeh Bakhtiari and Mester, {Jessica L} and Michael Granato and Karim-Jean Armache and Gregory Costain and Erica Korb",

year = "2024",

month = nov,

day = "2",

doi = "10.1101/2024.10.31.24314716",

language = "English",

series = "medRxiv",

publisher = "Cold Spring Harbor Laboratory Press",

address = "United States",

type = "WorkingPaper",

institution = "Cold Spring Harbor Laboratory Press",

}

Maroni, MJ, Barton, M, Lynch, K, Deshwar, AR, Campbell, P, Millard, J, Lee, R, Cohen, A, Paranjapye, A, Faundes, V, Repetto, GM, McKenna, C, Shillington, AL, Phornphutkul, C, Mancini, GM, Schot, R, Barakat, TS, Richmond, CM, Lauzon, J, Elsayed Ibrahim, AI, Benito, DN, Ortez, C, Estevez-Arias, B, Lecoquierre, F, Cassinari, K, Guerrot, A-M, Levy, J, Latypova, X, Verloes, A, Innes, AM, Banka, S, Vill, K, Jacob, M, Kruer, M, Skidmore, P, Galaz-Montoya, CI, Bakhtiari, S, Mester, JL, Granato, M, Armache, K-J, Costain, G & Korb, E 2024 'Loss of DOT1L function disrupts neuronal transcription, animal behavior, and leads to a novel neurodevelopmental disorder' medRxiv, Cold Spring Harbor Laboratory Press. https://doi.org/10.1101/2024.10.31.24314716

TY - UNPB

T1 - Loss of DOT1L function disrupts neuronal transcription, animal behavior, and leads to a novel neurodevelopmental disorder

AU - Maroni, Marissa J

AU - Barton, Melissa

AU - Lynch, Katherine

AU - Deshwar, Ashish R

AU - Campbell, Philip

AU - Millard, Josephine

AU - Lee, Rachel

AU - Cohen, Annastelle

AU - Paranjapye, Alekh

AU - Faundes, Víctor

AU - Repetto, Gabriela M

AU - McKenna, Caoimhe

AU - Shillington, Amelle L

AU - Phornphutkul, Chanika

AU - Mancini, Grazia Ms

AU - Schot, Rachel

AU - Barakat, Tahsin Stefan

AU - Richmond, Christopher M

AU - Lauzon, Julie

AU - Elsayed Ibrahim, Ahmed Ibrahim

AU - Benito, Daniel Natera-de

AU - Ortez, Carlos

AU - Estevez-Arias, Berta

AU - Lecoquierre, François

AU - Cassinari, Kévin

AU - Guerrot, Anne-Marie

AU - Levy, Jonathan

AU - Latypova, Xenia

AU - Verloes, Alain

AU - Innes, A Micheil

AU - Banka, Siddharth

AU - Vill, Katharina

AU - Jacob, Maureen

AU - Kruer, Michael

AU - Skidmore, Peter

AU - Galaz-Montoya, Carolina I

AU - Bakhtiari, Somayeh

AU - Mester, Jessica L

AU - Granato, Michael

AU - Armache, Karim-Jean

AU - Costain, Gregory

AU - Korb, Erica

PY - 2024/11/2

Y1 - 2024/11/2

N2 - Individuals with monoallelic pathogenic variants in the histone lysine methyltransferase DOT1L display global developmental delay and varying congenital anomalies. However, the impact of monoallelic loss of DOT1L remains unclear. Here, we present a largely female cohort of 11 individuals with DOT1L variants with developmental delays and dysmorphic facial features. We found that DOT1L variants include missense variants clustered in the catalytic domain, frameshift, and stop-gain variants. We demonstrate that specific variants cause loss of methyltransferase activity and therefore sought to define the effects of decreased DOT1L function. Using RNA-sequencing of cultured neurons and single nucleus RNA-sequencing of mouse cortical tissue, we found that partial Dot1l depletion causes sex-specific transcriptional responses and disrupts transcription of synaptic genes. Further, Dot1l loss alters neuron branching and expression of synaptic proteins. Lastly using zebrafish and mouse models, we found behavioral disruptions that include sex-specific deficits in mice. Overall, we define how DOT1L loss leads to neurological dysfunction by demonstrating that partial Dot1l loss impacts transcription, neuron morphology, and behavior across multiple models and systems.

AB - Individuals with monoallelic pathogenic variants in the histone lysine methyltransferase DOT1L display global developmental delay and varying congenital anomalies. However, the impact of monoallelic loss of DOT1L remains unclear. Here, we present a largely female cohort of 11 individuals with DOT1L variants with developmental delays and dysmorphic facial features. We found that DOT1L variants include missense variants clustered in the catalytic domain, frameshift, and stop-gain variants. We demonstrate that specific variants cause loss of methyltransferase activity and therefore sought to define the effects of decreased DOT1L function. Using RNA-sequencing of cultured neurons and single nucleus RNA-sequencing of mouse cortical tissue, we found that partial Dot1l depletion causes sex-specific transcriptional responses and disrupts transcription of synaptic genes. Further, Dot1l loss alters neuron branching and expression of synaptic proteins. Lastly using zebrafish and mouse models, we found behavioral disruptions that include sex-specific deficits in mice. Overall, we define how DOT1L loss leads to neurological dysfunction by demonstrating that partial Dot1l loss impacts transcription, neuron morphology, and behavior across multiple models and systems.

U2 - 10.1101/2024.10.31.24314716

DO - 10.1101/2024.10.31.24314716

M3 - Preprint

C2 - 39574879

T3 - medRxiv

BT - Loss of DOT1L function disrupts neuronal transcription, animal behavior, and leads to a novel neurodevelopmental disorder

PB - Cold Spring Harbor Laboratory Press

ER -

Loss of DOT1L function disrupts neuronal transcription, animal behavior, and leads to a novel neurodevelopmental disorder

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