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1. Neuroanatomy and behavior in mice with a haploinsufficiency of AT-rich interactive domain 1B (ARID1B) throughout development

Author

Ellegood, J, Petkova, SP, Kinman, A, Qiu, LR, Adhikari, A, Wade, AA, Fernandes, D, Lindenmaier, Z, Creighton, A, Nutter, LMJ, Nord, AS, Silverman, JL, and Lerch, JP

Subjects
Biological Psychology, Biomedical and Clinical Sciences, Psychology, Mental Health, Neurosciences, Behavioral and Social Science, Pediatric, Brain Disorders, Intellectual and Developmental Disabilities (IDD), Genetics, Basic Behavioral and Social Science, 2.1 Biological and endogenous factors, Aetiology, Neurological, Mental health, Animals, Behavior, Animal, Brain, Exploratory Behavior, Fear, Female, Gait, Haploinsufficiency, Learning, Magnetic Resonance Imaging, Male, Mice, Mutant Strains, Motor Skills, Neurodevelopmental Disorders, Recognition, Psychology, Social Behavior, Transcription Factors, Vocalization, Animal, Mice, Magnetic resonance imaging, Coffin&#8211, Siris syndrome, Autism, Arid1b, Mouse, Behavior, Coffin–Siris syndrome, Clinical Sciences, Clinical sciences, Biological psychology
Abstract

BackgroundOne of the causal mechanisms underlying neurodevelopmental disorders (NDDs) is chromatin modification and the genes that regulate chromatin. AT-rich interactive domain 1B (ARID1B), a chromatin modifier, has been linked to autism spectrum disorder and to affect rare and inherited genetic variation in a broad set of NDDs.MethodsA novel preclinical mouse model of Arid1b deficiency was created and validated to characterize and define neuroanatomical, behavioral and transcriptional phenotypes. Neuroanatomy was assessed ex vivo in adult animals and in vivo longitudinally from birth to adulthood. Behavioral testing was also performed throughout development and tested all aspects of motor, learning, sociability, repetitive behaviors, seizure susceptibility, and general milestones delays.ResultsWe validated decreased Arid1b mRNA and protein in Arid1b+/- mice, with signatures of increased axonal and synaptic gene expression, decreased transcriptional regulator and RNA processing expression in adult Arid1b+/- cerebellum. During neonatal development, Arid1b+/- mice exhibited robust impairments in ultrasonic vocalizations (USVs) and metrics of developmental growth. In addition, a striking sex effect was observed neuroanatomically throughout development. Behaviorally, as adults, Arid1b+/- mice showed low motor skills in open field exploration and normal three-chambered approach. Arid1b+/- mice had learning and memory deficits in novel object recognition but not in visual discrimination and reversal touchscreen tasks. Social interactions in the male-female social dyad with USVs revealed social deficits on some but not all parameters. No repetitive behaviors were observed. Brains of adult Arid1b+/- mice had a smaller cerebellum and a larger hippocampus and corpus callosum. The corpus callosum increase seen here contrasts previous reports which highlight losses in corpus callosum volume in mice and humans.LimitationsThe behavior and neuroimaging analyses were done on separate cohorts of mice, which did not allow a direct correlation between the imaging and behavioral findings, and the transcriptomic analysis was exploratory, with no validation of altered expression beyond Arid1b.ConclusionsThis study represents a full validation and investigation of a novel model of Arid1b+/- haploinsufficiency throughout development and highlights the importance of examining both sexes throughout development in NDDs.

Published
2021

2. Neuroanatomy and Behaviour in Mice with a Haploinsufficiency of AT-Rich Interactive Domain 1B (ARID1B) Throughout Development

Author

Ellegood, J, Petkova, SP, Kinman, A, Qiu, LR, Wade, A, Fernandes, D, Lindenmaier, Z, Crieghton, A, Nutter, L, Nord, AS, Silverman, JL, and Lerch, JP

Subjects
Genetics, Intellectual and Developmental Disabilities (IDD), Pediatric, Mental Health, Autism, Behavioral and Social Science, Neurosciences, Brain Disorders, Basic Behavioral and Social Science, 2.1 Biological and endogenous factors, 2.3 Psychological, social and economic factors, Mental health
Abstract

One of the causal mechanisms underlying neurodevelopmental disorders (NDDs) is chromatin modification, and genes that regulate chromatin modify and control events regulating the formation of neural connections. AT-Rich Interactive Domain 1B (ARID1B) , a chromatin modifier, has been shown to be reduced in autism spectrum disorder (ASD) and to affect rare and inherited genetic variation in a broad set of NDDs. For this work, a novel preclinical mouse model of Arid1b deficiency was created and molecularly validated to characterize and define neuroanatomical, behavioural and transcriptional phenotypes. Brains of adult Arid1b +/- mice had a smaller cerebellum along with a larger hippocampus and corpus callosum. In addition, a notable sex dependence was observed throughout development; males had an early emergence of the neuroanatomical phenotype around postnatal day 7, whereas females had a delayed emergence of the phenotype around postnatal day 40. Behavioural assays relevant to NDD were conducted during neonatal development and adulthood to evaluate general health, anxiety-like, motor, cognitive, and social behaviours in Arid1b +/- mice. During neonatal development, Arid1b +/- mice exhibited robust impairments in ultrasonic vocalizations (USVs) and metrics of developmental growth. As adults, Arid1b +/- mice showed low motor skills in open field exploration and normal three chambered approach. Arid1b +/- mice had learning and memory deficits in novel object recognition but surprisingly not in visual discrimination and reversal touchscreen tasks. Social interactions in the male-female social dyad with USVs revealed social deficits on some but not all parameters. No repetitive behaviours were observed. This study represents a full investigation of Arid1b +/- haploinsufficiency throughout development and highlights the importance of examining both sexes throughout development in NDDs.

Published
2020

3. Translational outcomes in a full gene deletion of ubiquitin protein ligase E3A rat model of Angelman syndrome.

Author

Berg, EL, Pride, MC, Petkova, SP, Lee, RD, Copping, NA, Shen, Y, Adhikari, A, Fenton, TA, Pedersen, LR, Noakes, LS, Nieman, BJ, Lerch, JP, Harris, S, Born, HA, Peters, MM, Deng, P, Cameron, DL, Fink, KD, Beitnere, U, O'Geen, H, Anderson, AE, Dindot, SV, Nash, KR, Weeber, EJ, Wöhr, M, Ellegood, J, Segal, DJ, and Silverman, JL

Subjects
Clinical Sciences, Public Health and Health Services, Psychology
Abstract

Angelman syndrome (AS) is a rare neurodevelopmental disorder characterized by developmental delay, impaired communication, motor deficits and ataxia, intellectual disabilities, microcephaly, and seizures. The genetic cause of AS is the loss of expression of UBE3A (ubiquitin protein ligase E6-AP) in the brain, typically due to a deletion of the maternal 15q11-q13 region. Previous studies have been performed using a mouse model with a deletion of a single exon of Ube3a. Since three splice variants of Ube3a exist, this has led to a lack of consistent reports and the theory that perhaps not all mouse studies were assessing the effects of an absence of all functional UBE3A. Herein, we report the generation and functional characterization of a novel model of Angelman syndrome by deleting the entire Ube3a gene in the rat. We validated that this resulted in the first comprehensive gene deletion rodent model. Ultrasonic vocalizations from newborn Ube3am-/p+ were reduced in the maternal inherited deletion group with no observable change in the Ube3am+/p- paternal transmission cohort. We also discovered Ube3am-/p+ exhibited delayed reflex development, motor deficits in rearing and fine motor skills, aberrant social communication, and impaired touchscreen learning and memory in young adults. These behavioral deficits were large in effect size and easily apparent in the larger rodent species. Low social communication was detected using a playback task that is unique to rats. Structural imaging illustrated decreased brain volume in Ube3am-/p+ and a variety of intriguing neuroanatomical phenotypes while Ube3am+/p- did not exhibit altered neuroanatomy. Our report identifies, for the first time, unique AS relevant functional phenotypes and anatomical markers as preclinical outcomes to test various strategies for gene and molecular therapies in AS.

Published
2020

6. Prenatal β-catenin/Brn2/Tbr2 transcriptional cascade regulates adult social and stereotypic behaviors.

Author

Belinson, H, Nakatani, J, Babineau, BA, Birnbaum, RY, Ellegood, J, Bershteyn, M, McEvilly, RJ, Long, JM, Willert, K, Klein, OD, Ahituv, N, Lerch, JP, Rosenfeld, MG, and Wynshaw-Boris, A

Subjects
Brain, Neurons, Animals, Humans, Mice, Adaptor Proteins, Signal Transducing, T-Box Domain Proteins, Nerve Tissue Proteins, Phosphoproteins, Behavior, Animal, Stereotyped Behavior, Stereotypic Movement Disorder, Signal Transduction, POU Domain Factors, Wnt Proteins, beta Catenin, Neural Stem Cells, Wnt Signaling Pathway, Dishevelled Proteins, Psychiatry, Biological Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences
Abstract

Social interaction is a fundamental behavior in all animal species, but the developmental timing of the social neural circuit formation and the cellular and molecular mechanisms governing its formation are poorly understood. We generated a mouse model with mutations in two Disheveled genes, Dvl1 and Dvl3, that displays adult social and repetitive behavioral abnormalities associated with transient embryonic brain enlargement during deep layer cortical neuron formation. These phenotypes were mediated by the embryonic expansion of basal neural progenitor cells (NPCs) via deregulation of a β-catenin/Brn2/Tbr2 transcriptional cascade. Transient pharmacological activation of the canonical Wnt pathway during this period of early corticogenesis rescued the β-catenin/Brn2/Tbr2 transcriptional cascade and the embryonic brain phenotypes. Remarkably, this embryonic treatment prevented adult behavioral deficits and partially rescued abnormal brain structure in Dvl mutant mice. Our findings define a mechanism that links fetal brain development and adult behavior, demonstrating a fetal origin for social and repetitive behavior deficits seen in disorders such as autism.

Published
2016

7. 3D visualization of the regional differences

Author

Ellegood, J, Anagnostou, E, Babineau, BA, Crawley, JN, Lin, L, Genestine, M, DiCicco-Bloom, E, Lai, JKY, Foster, JA, Peñagarikano, O, Geschwind, DH, Pacey, LK, Hampson, DR, Laliberté, CL, Mills, AA, Tam, E, Osborne, LR, Kouser, M, Espinosa-Becerra, F, Xuan, Z, Powell, CM, Raznahan, A, Robins, DM, Nakai, N, Nakatani, J, Takumi, T, van Eede, MC, Kerr, TM, Muller, C, Blakely, RD, Veenstra-VanderWeele, J, Henkelman, RM, and Lerch, JP

Subjects
Animals, Brain, Imaging, Three-Dimensional, Mice, Neuroimaging, Brain Disorders, Autism, Genetics, Neurosciences, Mental Health, Intellectual and Developmental Disabilities (IDD), Biomedical Imaging, 2.1 Biological and endogenous factors, Aetiology, Mental health, Neurological, Autistic Disorder, Disease Models, Animal, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Mice, Inbred BALB C, Mice, Transgenic, Multigene Family, Biological Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences, Psychiatry
Abstract

Autism is a heritable disorder, with over 250 associated genes identified to date, yet no single gene accounts for >1-2% of cases. The clinical presentation, behavioural symptoms, imaging and histopathology findings are strikingly heterogeneous. A more complete understanding of autism can be obtained by examining multiple genetic or behavioural mouse models of autism using magnetic resonance imaging (MRI)-based neuroanatomical phenotyping. Twenty-six different mouse models were examined and the consistently found abnormal brain regions across models were parieto-temporal lobe, cerebellar cortex, frontal lobe, hypothalamus and striatum. These models separated into three distinct clusters, two of which can be linked to the under and over-connectivity found in autism. These clusters also identified previously unknown connections between Nrxn1α, En2 and Fmr1; Nlgn3, BTBR and Slc6A4; and also between X monosomy and Mecp2. With no single treatment for autism found, clustering autism using neuroanatomy and identifying these strong connections may prove to be a crucial step in predicting treatment response.

Published
2015

8. Linking mouse and human brains to identify biologically significant clusters in autism spectrum

Author

Beauchamp, A., Ellegood, J., Yee, Y., Anagnostou, E., Ayub, M., Chakravarty, M.M., Crosbie, J., Devenyi, G.A., Georgiades, S., Iaboni, A., Jones, J.K., Kelley, E.A., Kushki, A., Mars, R.B., Nicolson, R., Schachar, R., Ziolkowski, J., Lerch, J.P., Beauchamp, A., Ellegood, J., Yee, Y., Anagnostou, E., Ayub, M., Chakravarty, M.M., Crosbie, J., Devenyi, G.A., Georgiades, S., Iaboni, A., Jones, J.K., Kelley, E.A., Kushki, A., Mars, R.B., Nicolson, R., Schachar, R., Ziolkowski, J., and Lerch, J.P.

Abstract

INSAR 2023: Annual Meeting International Society for Autism Research (INSAR) (Stockholm, Sweden, 306 May 2023), Item does not contain fulltext

Published
2023

10. Clustering autism: using neuroanatomical differences in 26 mouse models to gain insight into the heterogeneity

Author

Ellegood, J, Anagnostou, E, Babineau, B A, Crawley, J N, Lin, L, Genestine, M, DiCicco-Bloom, E, Lai, J K Y, Foster, J A, Peñagarikano, O, Geschwind, D H, Pacey, L K, Hampson, D R, Laliberté, C L, Mills, A A, Tam, E, Osborne, L R, Kouser, M, Espinosa-Becerra, F, Xuan, Z, Powell, C M, Raznahan, A, Robins, D M, Nakai, N, Nakatani, J, Takumi, T, van Eede, M C, Kerr, T M, Muller, C, Blakely, R D, Veenstra-VanderWeele, J, Henkelman, R M, and Lerch, J P

Published
2015
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15. Brain mapping across 16 autism mouse models reveals a spectrum of functional connectivity subtypes

Author

Zerbi, V; https://orcid.org/0000-0001-7984-9565, Pagani, M; https://orcid.org/0000-0002-6052-6931, Markicevic, M, Matteoli, M; https://orcid.org/0000-0002-3569-7843, Pozzi, D; https://orcid.org/0000-0001-6436-0556, Fagiolini, M; https://orcid.org/0000-0003-2807-803X, Bozzi, Y, Galbusera, A; https://orcid.org/0000-0001-7213-0013, Scattoni, M L, Provenzano, G, Banerjee, A; https://orcid.org/0000-0002-5649-6469, Helmchen, F; https://orcid.org/0000-0002-8867-9569, Basson, M A; https://orcid.org/0000-0001-9834-7528, Ellegood, J; https://orcid.org/0000-0003-1504-3321, Lerch, J P, Rudin, M, Gozzi, A; https://orcid.org/0000-0002-5731-4137, Wenderoth, N, Zerbi, V; https://orcid.org/0000-0001-7984-9565, Pagani, M; https://orcid.org/0000-0002-6052-6931, Markicevic, M, Matteoli, M; https://orcid.org/0000-0002-3569-7843, Pozzi, D; https://orcid.org/0000-0001-6436-0556, Fagiolini, M; https://orcid.org/0000-0003-2807-803X, Bozzi, Y, Galbusera, A; https://orcid.org/0000-0001-7213-0013, Scattoni, M L, Provenzano, G, Banerjee, A; https://orcid.org/0000-0002-5649-6469, Helmchen, F; https://orcid.org/0000-0002-8867-9569, Basson, M A; https://orcid.org/0000-0001-9834-7528, Ellegood, J; https://orcid.org/0000-0003-1504-3321, Lerch, J P, Rudin, M, Gozzi, A; https://orcid.org/0000-0002-5731-4137, and Wenderoth, N

Abstract

Autism Spectrum Disorder (ASD) is characterized by substantial, yet highly heterogeneous abnormalities in functional brain connectivity. However, the origin and significance of this phenomenon remain unclear. To unravel ASD connectopathy and relate it to underlying etiological heterogeneity, we carried out a bi-center cross-etiological investigation of fMRI-based connectivity in the mouse, in which specific ASD-relevant mutations can be isolated and modeled minimizing environmental contributions. By performing brain-wide connectivity mapping across 16 mouse mutants, we show that different ASD-associated etiologies cause a broad spectrum of connectional abnormalities in which diverse, often diverging, connectivity signatures are recognizable. Despite this heterogeneity, the identified connectivity alterations could be classified into four subtypes characterized by discrete signatures of network dysfunction. Our findings show that etiological variability is a key determinant of connectivity heterogeneity in ASD, hence reconciling conflicting findings in clinical populations. The identification of etiologically-relevant connectivity subtypes could improve diagnostic label accuracy in the non-syndromic ASD population and paves the way for personalized treatment approaches.

Published
2021

17. Brain mapping across 16 autism mouse models reveals a spectrum of functional connectivity subtypes

Author

Zerbi, V., primary, Pagani, M., additional, Markicevic, M., additional, Matteoli, M., additional, Pozzi, D., additional, Fagiolini, M., additional, Bozzi, Y., additional, Galbusera, A., additional, Scattoni, ML, additional, Provenzano, G., additional, Banerjee, A., additional, Helmchen, F., additional, Albert Basson, M., additional, Ellegood, J., additional, Lerch, J. P., additional, Rudin, M., additional, Gozzi, A., additional, and Wenderoth, N., additional

Published
2020
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20. Distinct cerebellar foliation anomalies in a Chd7 haploinsufficient mouse model of CHARGE syndrome

Author

Whittaker, D E, Kasah, S, Donovan, A P A, Ellegood, J, Riegman, K L H, Volk, H A, McGonnell, I M, Lerch, J P, and Basson, A

Abstract

Mutations in the gene encoding the ATP dependent chromatin‐remodeling factor, CHD7 are the major cause of CHARGE (Coloboma, Heart defects, Atresia of the choanae, Retarded growth and development, Genital‐urinary anomalies, and Ear defects) syndrome. Neurodevelopmental defects and a range of neurological signs have been identified in individuals with CHARGE syndrome, including developmental delay, lack of coordination, intellectual disability, and autistic traits. We previously identified cerebellar vermis hypoplasia and abnormal cerebellar foliation in individuals with CHARGE syndrome. Here, we report mild cerebellar hypoplasia and distinct cerebellar foliation anomalies in a Chd7 haploinsufficient mouse model. We describe specific alterations in the precise spatio‐temporal sequence of fissure formation during perinatal cerebellar development responsible for these foliation anomalies. The altered cerebellar foliation pattern in Chd7 haploinsufficient mice show some similarities to those reported in mice with altered Engrailed, Fgf8 or Zic1 gene expression and we propose that mutations or polymorphisms in these genes may modify the cerebellar phenotype in CHARGE syndrome. Our findings in a mouse model of CHARGE syndrome indicate that a careful analysis of cerebellar foliation may be warranted in patients with CHARGE syndrome, particularly in patients with cerebellar hypoplasia and developmental delay.

Published
2017

22. Neuroanatomical phenotypes in a mouse model of the 22q11.2 microdeletion

Author

Ellegood, J., Markx, S., Lerch, J.P. (Jason), Steadman, P.E., Genç, C.G. (Cansu), Provenzano, F., Kushner, S.A. (Steven), Henkelman, R.M., Karayiorgou, M., Gogos, J.A., Ellegood, J., Markx, S., Lerch, J.P. (Jason), Steadman, P.E., Genç, C.G. (Cansu), Provenzano, F., Kushner, S.A. (Steven), Henkelman, R.M., Karayiorgou, M., and Gogos, J.A.

Abstract

Recurrent deletions at the 22q11.2 locus have been established as a strong genetic risk factor for the development of schizophrenia and cognitive dysfunction. Individuals with 22q11.2 deletions have a range of well-defined volumetric abnormalities in a number of critical brain structures. A mouse model of the 22q11.2 deletion (Df(16)A+/-) has previously been utilized to characterize disease-associated abnormalities on synaptic, cellular, neurocircuitry, and behavioral levels. We performed a high-resolution MRI analysis of mutant mice compared with wild-type littermates. Our analysis revealed a striking similarity in the specific volumetric changes of Df(16)A+/-mice compared with human 22q11.2 deletion carriers, including in cortico-cerebellar, cortico-striatal and cortico-limbic circuits. In addition, higher resolution magnetic resonance imaging compared with neuroimaging in human subjects allowed the detection of previously unknown subtle local differences. The cerebellar findings in Df(16)A+/-mice are particularly instructive as they are localized to specific areas within both the deep cerebellar nuclei and the cerebellar cortex. Our study indicates that the Df(16)A+/-mouse model recapitulates most of the hallmark neuroanatomical changes observed in 22q11.2 deletion carriers. Our findings will help guide the design and interpretation of additional complementary studies and thereby advance our understanding of the abnormal brain development underlying the emergence of 22q11.2 deletion-associated psychiatric and cognitive symptoms.Molecular Psychiatry advance online publication, 3 September 2013; doi:10.1038/mp.2013.112.

Published
2014
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23. Clustering autism: using neuroanatomical differences in 26 mouse models to gain insight into the heterogeneity

Author

Ellegood, J, primary, Anagnostou, E, additional, Babineau, B A, additional, Crawley, J N, additional, Lin, L, additional, Genestine, M, additional, DiCicco-Bloom, E, additional, Lai, J K Y, additional, Foster, J A, additional, Peñagarikano, O, additional, Geschwind, D H, additional, Pacey, L K, additional, Hampson, D R, additional, Laliberté, C L, additional, Mills, A A, additional, Tam, E, additional, Osborne, L R, additional, Kouser, M, additional, Espinosa-Becerra, F, additional, Xuan, Z, additional, Powell, C M, additional, Raznahan, A, additional, Robins, D M, additional, Nakai, N, additional, Nakatani, J, additional, Takumi, T, additional, van Eede, M C, additional, Kerr, T M, additional, Muller, C, additional, Blakely, R D, additional, Veenstra-VanderWeele, J, additional, Henkelman, R M, additional, and Lerch, J P, additional

Published
2014
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27. Prenatal ß-catenin/Brn2/Tbr2 transcriptional cascade regulates adult social and stereotypic behaviors

Author

Belinson, H, Nakatani, J, Babineau, B A, Birnbaum, R Y, Ellegood, J, Bershteyn, M, McEvilly, R J, Long, J M, Willert, K, Klein, O D, Ahituv, N, Lerch, J P, Rosenfeld, M G, and Wynshaw-Boris, A

Abstract

Social interaction is a fundamental behavior in all animal species, but the developmental timing of the social neural circuit formation and the cellular and molecular mechanisms governing its formation are poorly understood. We generated a mouse model with mutations in two Disheveled genes, Dvl1and Dvl3, that displays adult social and repetitive behavioral abnormalities associated with transient embryonic brain enlargement during deep layer cortical neuron formation. These phenotypes were mediated by the embryonic expansion of basal neural progenitor cells (NPCs) via deregulation of a ß-catenin/Brn2/Tbr2 transcriptional cascade. Transient pharmacological activation of the canonical Wnt pathway during this period of early corticogenesis rescued the ß-catenin/Brn2/Tbr2 transcriptional cascade and the embryonic brain phenotypes. Remarkably, this embryonic treatment prevented adult behavioral deficits and partially rescued abnormal brain structure in Dvlmutant mice. Our findings define a mechanism that links fetal brain development and adult behavior, demonstrating a fetal origin for social and repetitive behavior deficits seen in disorders such as autism.

Published
2016
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34. Synthesis of the complexes [PdCIR(cod)] (R = benzyl, ethyl; cod = 1,5-cyclooctadiene). β-Elimination from [PdCIEt(cod)] to give the η1,η2and η3isomers of [Pd2(μ-Cl)2(C8H13)2]

Author

Stockland Jr., Robert A., Anderson, Gordon K., Rath, Nigam P., Braddock-Wilking, Janet, and Ellegood, J. Christopher

Abstract

Treatment of [PdCl2(cod)] with tetrabenzyltin gives the benzylpalladium complex [PdCl(CH2Ph)(cod)] (cod = 1,5-cyclooctadiene), 1a, whose structure has been determined by X-ray crystallography. It adopts approximate square-planar geometry, with the double bonds perpendicular to the square plane. The corresponding ethylpalladium derivative 1bhas been prepared by a similar method, but it is considerably less stable. It decomposes by (β-elimination to produce ethene and a transient hydride complex, which either undergoes migratory insertion to give [Pd2(μ-Cl)2(η1,η2-C8H13)2], 2a, or dinuclear reductive elimination with a second molecule of 1bto produce ethane, [PdCl2(cod)], free cyclooctadiene, and palladium metal. Complex 2ahas also been prepared by reaction of [PdCl2(cod)] with NaBH4. At higher temperatures 2aconverts to an equilibrium mixture with its η3-allyl isomer, 2b. Reactions of [PdCl2(cod)] or K2PdCl4in the presence of cyclooctadiene in aqueous solution to produce 2aor 2bhave also been investigated. Keywords: palladium, diene complexes, allyl complexes, isomerization, β-elimination.

Published
1996
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39. The universe is asymmetric, the mouse brain too.

Author

Rivera-Olvera A, Houwing DJ, Ellegood J, Masifi S, Martina SL, Silberfeld A, Pourquie O, Lerch JP, Francks C, Homberg JR, van Heukelum S, and Grandjean J

Abstract

Hemispheric brain asymmetry is a basic organizational principle of the human brain and has been implicated in various psychiatric conditions, including autism spectrum disorder. Brain asymmetry is not a uniquely human feature and is observed in other species such as the mouse. Yet, asymmetry patterns are generally nuanced, and substantial sample sizes are required to detect these patterns. In this pre-registered study, we use a mouse dataset from the Province of Ontario Neurodevelopmental Network, which comprises structural MRI data from over 2000 mice, including genetic models for autism spectrum disorder, to reveal the scope and magnitude of hemispheric asymmetry in the mouse. Our findings demonstrate the presence of robust hemispheric asymmetry in the mouse brain, such as larger right hemispheric volumes towards the anterior pole and larger left hemispheric volumes toward the posterior pole, opposite to what has been shown in humans. This suggests the existence of species-specific traits. Further clustering analysis identified distinct asymmetry patterns in autism spectrum disorder models, a phenomenon that is also seen in atypically developing participants. Our study shows potential for the use of mouse models to understand the biological bases of typical and atypical brain asymmetry but also warrants caution as asymmetry patterns seem to differ between humans and mice., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published
2024
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40. The mouse motor system contains multiple premotor areas and partially follows human organizational principles.

Author

Lazari A, Tachrount M, Valverde JM, Papp D, Beauchamp A, McCarthy P, Ellegood J, Grandjean J, Johansen-Berg H, Zerbi V, Lerch JP, and Mars RB

Subjects
Humans, Animals, Mice, Male, Mice, Inbred C57BL, Adult, Female, Brain Mapping, Motor Cortex physiology
Abstract

While humans are known to have several premotor cortical areas, secondary motor cortex (M2) is often considered to be the only higher-order motor area of the mouse brain and is thought to combine properties of various human premotor cortices. Here, we show that axonal tracer, functional connectivity, myelin mapping, gene expression, and optogenetics data contradict this notion. Our analyses reveal three premotor areas in the mouse, anterior-lateral motor cortex (ALM), anterior-lateral M2 (aM2), and posterior-medial M2 (pM2), with distinct structural, functional, and behavioral properties. By using the same techniques across mice and humans, we show that ALM has strikingly similar functional and microstructural properties to human anterior ventral premotor areas and that aM2 and pM2 amalgamate properties of human pre-SMA and cingulate cortex. These results provide evidence for the existence of multiple premotor areas in the mouse and chart a comparative map between the motor systems of humans and mice., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published
2024
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41. Comparative neuroimaging of sex differences in human and mouse brain anatomy.

Author

Guma E, Beauchamp A, Liu S, Levitis E, Ellegood J, Pham L, Mars RB, Raznahan A, and Lerch JP

Subjects
Humans, Male, Female, Mice, Animals, Neuroimaging methods, Magnetic Resonance Imaging methods, Mammals, Sex Characteristics, Brain diagnostic imaging, Brain anatomy & histology
Abstract

In vivo neuroimaging studies have established several reproducible volumetric sex differences in the human brain, but the causes of such differences are hard to parse. While mouse models are useful for understanding the cellular and mechanistic bases of sex-specific brain development, there have been no attempts to formally compare human and mouse neuroanatomical sex differences to ascertain how well they translate. Addressing this question would shed critical light on the use of the mouse as a translational model for sex differences in the human brain and provide insights into the degree to which sex differences in brain volume are conserved across mammals. Here, we use structural magnetic resonance imaging to conduct the first comparative neuroimaging study of sex-specific neuroanatomy of the human and mouse brain. In line with previous findings, we observe that in humans, males have significantly larger and more variable total brain volume; these sex differences are not mirrored in mice. After controlling for total brain volume, we observe modest cross-species congruence in the volumetric effect size of sex across 60 homologous regions ( r =0.30). This cross-species congruence is greater in the cortex ( r =0.33) than non-cortex ( r =0.16). By incorporating regional measures of gene expression in both species, we reveal that cortical regions with greater cross-species congruence in volumetric sex differences also show greater cross-species congruence in the expression profile of 2835 homologous genes. This phenomenon differentiates primary sensory regions with high congruence of sex effects and gene expression from limbic cortices where congruence in both these features was weaker between species. These findings help identify aspects of sex-biased brain anatomy present in mice that are retained, lost, or inverted in humans. More broadly, our work provides an empirical basis for targeting mechanistic studies of sex-specific brain development in mice to brain regions that best echo sex-specific brain development in humans., Competing Interests: EG, AB, SL, EL, JE, LP, RM, AR, JL No competing interests declared

Published
2024
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42. Organization of thalamocortical structural covariance and a corresponding 3D atlas of the mouse thalamus.

Author

Yee Y, Ellegood J, French L, and Lerch JP

Subjects
Mice, Animals, Neural Pathways, Brain, Thalamus diagnostic imaging, Cerebral Cortex diagnostic imaging, Brain Mapping methods, Magnetic Resonance Imaging methods
Abstract

For information from sensory organs to be processed by the brain, it is usually passed to appropriate areas of the cerebral cortex. Almost all of this information passes through the thalamus, a relay structure that reciprocally connects to the vast majority of the cortex. The thalamus facilitates this information transfer through a set of thalamocortical connections that vary in cellular structure, molecular profiles, innervation patterns, and firing rates. Additionally, corticothalamic connections allow for intracortical information transfer through the thalamus. These efferent and afferent connections between the thalamus and cortex have been the focus of many studies, and the importance of cortical connectivity in defining thalamus anatomy is demonstrated by multiple studies that parcellate the thalamus based on cortical connectivity profiles. Here, we examine correlated morphological variation between the thalamus and cortex, or thalamocortical structural covariance. For each voxel in the thalamus as a seed, we construct a cortical structural covariance map that represents correlated cortical volume variation, and examine whether high structural covariance is observed in cortical areas that are functionally relevant to the seed. Then, using these cortical structural covariance maps as features, we subdivide the thalamus into six non-overlapping regions (clusters of voxels), and assess whether cortical structural covariance is associated with cortical connectivity that specifically originates from these regions. We show that cortical structural covariance is high in areas of the cortex that are functionally related to the seed voxel, cortical structural covariance varies along cortical depth, and sharp transitions in cortical structural covariance profiles are observed when varying seed locations in the thalamus. Subdividing the thalamus based on structural covariance, we additionally demonstrate that the six thalamic clusters of voxels stratify cortical structural covariance along the dorsal-ventral, medial-lateral, and anterior-posterior axes. These cluster-associated structural covariance patterns are prominently detected in cortical regions innervated by fibers projecting out of their related thalamic subdivisions. Together, these results advance our understanding of how the thalamus and the cortex couple in their volumes. Our results indicate that these volume correlations reflect functional organization and structural connectivity, and further provides a novel segmentation of the mouse thalamus that can be used to examine thalamic structural variation and thalamocortical structural covariation in disease models., Competing Interests: Declaration of competing interest None., (Copyright © 2023. Published by Elsevier Inc.)

Published
2024
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43. Peripheral blood DNA methylation and neuroanatomical responses to HDACi treatment that rescues neurological deficits in a Kabuki syndrome mouse model.

Author

Goodman SJ, Luperchio TR, Ellegood J, Chater-Diehl E, Lerch JP, Bjornsson HT, and Weksberg R

Subjects
Humans, Animals, Mice, Neuroanatomy, Biomarkers, DNA Methylation, Histone Deacetylase Inhibitors pharmacology, Histone Deacetylase Inhibitors therapeutic use
Abstract

Background: Recent findings from studies of mouse models of Mendelian disorders of epigenetic machinery strongly support the potential for postnatal therapies to improve neurobehavioral and cognitive deficits. As several of these therapies move into human clinical trials, the search for biomarkers of treatment efficacy is a priority. A potential postnatal treatment of Kabuki syndrome type 1 (KS1), caused by pathogenic variants in KMT2D encoding a histone-lysine methyltransferase, has emerged using a mouse model of KS1 (Kmt2d +/βGeo ). In this mouse model, hippocampal memory deficits are ameliorated following treatment with the histone deacetylase inhibitor (HDACi), AR-42. Here, we investigate the effect of both Kmt2d +/βGeo genotype and AR-42 treatment on neuroanatomy and on DNA methylation (DNAm) in peripheral blood. While peripheral blood may not be considered a "primary tissue" with respect to understanding the pathophysiology of neurodevelopmental disorders, it has the potential to serve as an accessible biomarker of disease- and treatment-related changes in the brain., Methods: Half of the KS1 and wildtype mice were treated with 14 days of AR-42. Following treatment, fixed brain samples were imaged using MRI to calculate regional volumes. Blood was assayed for genome-wide DNAm at over 285,000 CpG sites using the Illumina Infinium Mouse Methylation array. DNAm patterns and brain volumes were analyzed in the four groups of animals: wildtype untreated, wildtype AR-42 treated, KS1 untreated and KS1 AR-42 treated., Results: We defined a DNAm signature in the blood of KS1 mice, that overlapped with the human KS1 DNAm signature. We also found a striking 10% decrease in total brain volume in untreated KS1 mice compared to untreated wildtype, which correlated with DNAm levels in a subset KS1 signature sites, suggesting that disease severity may be reflected in blood DNAm. Treatment with AR-42 ameliorated DNAm aberrations in KS1 mice at a small number of signature sites., Conclusions: As this treatment impacts both neurological deficits and blood DNAm in mice, future KS clinical trials in humans could be used to assess blood DNAm as an early biomarker of therapeutic efficacy., (© 2023. The Author(s).)

Published
2023
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44. Comparative neuroimaging of sex differences in human and mouse brain anatomy.

Author

Guma E, Beauchamp A, Liu S, Levitis E, Ellegood J, Pham L, Mars RB, Raznahan A, and Lerch JP

Abstract

In vivo neuroimaging studies have established several reproducible volumetric sex differences in the human brain, but the causes of such differences are hard to parse. While mouse models are useful for understanding the cellular and mechanistic bases of sex-biased brain development in mammals, there have been no attempts to formally compare mouse and human sex differences across the whole brain to ascertain how well they translate. Addressing this question would shed critical light on use of the mouse as a translational model for sex differences in the human brain and provide insights into the degree to which sex differences in brain volume are conserved across mammals. Here, we use cross-species structural magnetic resonance imaging to carry out the first comparative neuroimaging study of sex-biased neuroanatomical organization of the human and mouse brain. In line with previous findings, we observe that in humans, males have significantly larger and more variable total brain volume; these sex differences are not mirrored in mice. After controlling for total brain volume, we observe modest cross-species congruence in the volumetric effect size of sex across 60 homologous brain regions (r=0.30; e.g.: M>F amygdala, hippocampus, bed nucleus of the stria terminalis, and hypothalamus and F>M anterior cingulate, somatosensory, and primary auditory cortices). This cross-species congruence is greater in the cortex (r=0.33) than non-cortex (r=0.16). By incorporating regional measures of gene expression in both species, we reveal that cortical regions with greater cross-species congruence in volumetric sex differences also show greater cross-species congruence in the expression profile of 2835 homologous genes. This phenomenon differentiates primary sensory regions with high congruence of sex effects and gene expression from limbic cortices where congruence in both these features was weaker between species. These findings help identify aspects of sex-biased brain anatomy present in mice that are retained, lost, or inverted in humans. More broadly, our work provides an empirical basis for targeting mechanistic studies of sex-biased brain development in mice to brain regions that best echo sex-biased brain development in humans., Competing Interests: Conflict of interest statement The authors declare no competing financial interests.

Published
2023
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45. Brain structure and working memory adaptations associated with maturation and aging in mice.

Author

Clifford KP, Miles AE, Prevot TD, Misquitta KA, Ellegood J, Lerch JP, Sibille E, Nikolova YS, and Banasr M

Abstract

Introduction: As the population skews toward older age, elucidating mechanisms underlying human brain aging becomes imperative. Structural MRI has facilitated non-invasive investigation of lifespan brain morphology changes, yet this domain remains uncharacterized in rodents despite increasing use as models of disordered human brain aging., Methods: Young (2m, n = 10), middle-age (10m, n = 10) and old (22m, n = 9) mice were utilized for maturational (young vs. middle-age) and aging-related (middle-age vs. old mice) comparisons. Regional brain volume was averaged across hemispheres and reduced to 32 brain regions. Pairwise group differences in regional volume were tested using general linear models, with total brain volume as a covariate. Sample-wide associations between regional brain volume and Y-maze performance were assessed using logistic regression, residualized for total brain volume. Both analyses corrected for multiple comparisons. Structural covariance networks were generated using the R package "igraph." Group differences in network centrality (degree), integration (mean distance), and segregation (transitivity, modularity) were tested across network densities (5-40%), using 5,000 (1,000 for degree) permutations with significance criteria of p < 0.05 at ≥5 consecutive density thresholds., Results: Widespread significant maturational changes in volume occurred in 18 brain regions, including considerable loss in isocortex regions and increases in brainstem regions and white matter tracts. The aging-related comparison yielded 6 significant changes in brain volume, including further loss in isocortex regions and increases in white matter tracts. No significant volume changes were observed across either comparison for subcortical regions. Additionally, smaller volume of the anterior cingulate area (χ 2 = 2.325, p BH = 0.044) and larger volume of the hippocampal formation (χ 2 = -2.180, p BH = 0.044) were associated with poorer cognitive performance. Maturational network comparisons yielded significant degree changes in 9 regions, but no aging-related changes, aligning with network stabilization trends in humans. Maturational decline in modularity occurred (24-29% density), mirroring human trends of decreased segregation in young adulthood, while mean distance and transitivity remained stable., Conclusion/implications: These findings offer a foundational account of age effects on brain volume, structural brain networks, and working memory in mice, informing future work in facilitating translation between rodent models and human brain aging., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Clifford, Miles, Prevot, Misquitta, Ellegood, Lerch, Sibille, Nikolova and Banasr.)

Published
2023
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46. Pervasive cortical and white matter anomalies in a mouse model for CHARGE syndrome.

Author

Donovan APA, Rosko L, Ellegood J, Redhead Y, Green JBA, Lerch JP, Huang JK, and Basson MA

Subjects
Mice, Animals, Diffusion Tensor Imaging, CHARGE Syndrome genetics, White Matter diagnostic imaging, Autism Spectrum Disorder diagnostic imaging, Coloboma genetics
Abstract

CHARGE (Coloboma of the eye, Heart defects, Atresia of the choanae, Retardation of growth, Genital anomalies and Ear abnormalities) syndrome is a disorder caused by mutations in the gene encoding CHD7, an ATP dependent chromatin remodelling factor, and is characterised by a diverse array of congenital anomalies. These include a range of neuroanatomical comorbidities which likely underlie the varied neurodevelopmental disorders associated with CHARGE syndrome, which include intellectual disability, motor coordination deficits, executive dysfunction, and autism spectrum disorder. Cranial imaging studies are challenging in CHARGE syndrome patients, but high-throughput magnetic resonance imaging (MRI) techniques in mouse models allow for the unbiased identification of neuroanatomical defects. Here, we present a comprehensive neuroanatomical survey of a Chd7 haploinsufficient mouse model of CHARGE syndrome. Our study uncovered widespread brain hypoplasia and reductions in white matter volume across the brain. The severity of hypoplasia appeared more pronounced in posterior areas of the neocortex compared to anterior regions. We also perform the first assessment of white matter tract integrity in this model through diffusion tensor imaging (DTI) to assess the potential functional consequences of widespread reductions in myelin, which suggested the presence of white matter integrity defects. To determine if white matter alterations correspond to cellular changes, we quantified oligodendrocyte lineage cells in the postnatal corpus callosum, uncovering reduced numbers of mature oligodendrocytes. Together, these results present a range of promising avenues of focus for future cranial imaging studies in CHARGE syndrome patients., (© 2023 The Authors. Journal of Anatomy published by John Wiley & Sons Ltd on behalf of Anatomical Society.)

Published
2023
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47. Sex bias in social deficits, neural circuits and nutrient demand in Cttnbp2 autism models.

Author

Yen TL, Huang TN, Lin MH, Hsu TT, Lu MH, Shih PY, Ellegood J, Lerch J, and Hsueh YP

Subjects
Mice, Male, Female, Animals, Proteomics, Sexism, TOR Serine-Threonine Kinases, Nutrients, Zinc, Disease Models, Animal, Nerve Tissue Proteins genetics, Microfilament Proteins, Autistic Disorder genetics, Autism Spectrum Disorder genetics
Abstract

Autism spectrum disorders caused by both genetic and environmental factors are strongly male-biased neuropsychiatric conditions. However, the mechanism underlying the sex bias of autism spectrum disorders remains elusive. Here, we use a mouse model in which the autism-linked gene Cttnbp2 is mutated to explore the potential mechanism underlying the autism sex bias. Autism-like features of Cttnbp2 mutant mice were assessed via behavioural assays. C-FOS staining identified sex-biased brain regions critical to social interaction, with their roles and connectivity then validated by chemogenetic manipulation. Proteomic and bioinformatic analyses established sex-biased molecular deficits at synapses, prompting our hypothesis that male-biased nutrient demand magnifies Cttnbp2 deficiency. Accordingly, intakes of branched-chain amino acids (BCAA) and zinc were experimentally altered to assess their effect on autism-like behaviours. Both deletion and autism-linked mutation of Cttnbp2 result in male-biased social deficits. Seven brain regions, including the infralimbic area of the medial prefrontal cortex (ILA), exhibit reduced neural activity in male mutant mice but not in females upon social stimulation. ILA activation by chemogenetic manipulation is sufficient to activate four of those brain regions susceptible to Cttnbp2 deficiency and consequently to ameliorate social deficits in male mice, implying an ILA-regulated neural circuit is critical to male-biased social deficits. Proteomics analysis reveals male-specific downregulated proteins (including SHANK2 and PSD-95, two synaptic zinc-binding proteins) and female-specific upregulated proteins (including RRAGC) linked to neuropsychiatric disorders, which are likely relevant to male-biased deficits and a female protective effect observed in Cttnbp2 mutant mice. Notably, RRAGC is an upstream regulator of mTOR that senses BCAA, suggesting that mTOR exerts a beneficial effect on females. Indeed, increased BCAA intake activates the mTOR pathway and rescues neuronal responses and social behaviours of male Cttnbp2 mutant mice. Moreover, mutant males exhibit greatly increased zinc demand to display normal social behaviours. Mice carrying an autism-linked Cttnbp2 mutation exhibit male-biased social deficits linked to specific brain regions, differential synaptic proteomes and higher demand for BCAA and zinc. We postulate that lower demand for zinc and BCAA are relevant to the female protective effect. Our study reveals a mechanism underlying sex-biased social defects and also suggests a potential therapeutic approach for autism spectrum disorders., (© The Author(s) 2022. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published
2023
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48. An old model with new insights: endogenous retroviruses drive the evolvement toward ASD susceptibility and hijack transcription machinery during development.

Author

Lin CW, Ellegood J, Tamada K, Miura I, Konda M, Takeshita K, Atarashi K, Lerch JP, Wakana S, McHugh TJ, and Takumi T

Subjects
Pregnancy, Female, Humans, Animals, Mice, DNA Copy Number Variations, Prosencephalon metabolism, Corpus Callosum pathology, Disease Models, Animal, Mice, Inbred C57BL, Mice, Inbred Strains, Endogenous Retroviruses genetics, Autistic Disorder etiology, Autism Spectrum Disorder genetics, Autism Spectrum Disorder complications
Abstract

The BTBR T + Itpr3 tf /J (BTBR/J) strain is one of the most valid models of idiopathic autism, serving as a potent forward genetics tool to dissect the complexity of autism. We found that a sister strain with an intact corpus callosum, BTBR TF/ArtRbrc (BTBR/R), showed more prominent autism core symptoms but moderate ultrasonic communication/normal hippocampus-dependent memory, which may mimic autism in the high functioning spectrum. Intriguingly, disturbed epigenetic silencing mechanism leads to hyperactive endogenous retrovirus (ERV), a mobile genetic element of ancient retroviral infection, which increases de novo copy number variation (CNV) formation in the two BTBR strains. This feature makes the BTBR strain a still evolving multiple-loci model toward higher ASD susceptibility. Furthermore, active ERV, analogous to virus infection, evades the integrated stress response (ISR) of host defense and hijacks the transcriptional machinery during embryonic development in the BTBR strains. These results suggest dual roles of ERV in the pathogenesis of ASD, driving host genome evolution at a long-term scale and managing cellular pathways in response to viral infection, which has immediate effects on embryonic development. The wild-type Draxin expression in BTBR/R also makes this substrain a more precise model to investigate the core etiology of autism without the interference of impaired forebrain bundles as in BTBR/J., (© 2023. The Author(s).)

Published
2023
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49. 17q12 deletion syndrome mouse model shows defects in craniofacial, brain and kidney development, and glucose homeostasis.

Author

Warren EB, Briano JA, Ellegood J, DeYoung T, Lerch JP, and Morrow EM

Subjects
Female, Humans, Male, Mice, Animals, Adult, Mice, Inbred C57BL, Syndrome, Disease Models, Animal, Glucose, Chromosome Deletion, Kidney, Brain
Abstract

17q12 deletion (17q12Del) syndrome is a copy number variant (CNV) disorder associated with neurodevelopmental disorders and renal cysts and diabetes syndrome (RCAD). Using CRISPR/Cas9 genome editing, we generated a mouse model of 17q12Del syndrome on both inbred (C57BL/6N) and outbred (CD-1) genetic backgrounds. On C57BL/6N, the 17q12Del mice had severe head development defects, potentially mediated by haploinsufficiency of Lhx1, a gene within the interval that controls head development. Phenotypes included brain malformations, particularly disruption of the telencephalon and craniofacial defects. On the CD-1 background, the 17q12Del mice survived to adulthood and showed milder craniofacial and brain abnormalities. We report postnatal brain defects using automated magnetic resonance imaging-based morphometry. In addition, we demonstrate renal and blood glucose abnormalities relevant to RCAD. On both genetic backgrounds, we found sex-specific presentations, with male 17q12Del mice exhibiting higher penetrance and more severe phenotypes. Results from these experiments pinpoint specific developmental defects and pathways that guide clinical studies and a mechanistic understanding of the human 17q12Del syndrome. This mouse mutant represents the first and only experimental model to date for the 17q12 CNV disorder. This article has an associated First Person interview with the first author of the paper., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2022. Published by The Company of Biologists Ltd.)

Published
2022
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50. TAOK2 rescues autism-linked developmental deficits in a 16p11.2 microdeletion mouse model.

Author

Scharrenberg R, Richter M, Johanns O, Meka DP, Rücker T, Murtaza N, Lindenmaier Z, Ellegood J, Naumann A, Zhao B, Schwanke B, Sedlacik J, Fiehler J, Hanganu-Opatz IL, Lerch JP, Singh KK, and de Anda FC

Subjects
Animals, Humans, Mice, Disease Models, Animal, Microtubules genetics, Microtubules metabolism, Neurogenesis genetics, Neurogenesis physiology, Autism Spectrum Disorder genetics, Autistic Disorder genetics, Neocortex metabolism, Protein Serine-Threonine Kinases genetics, Protein Serine-Threonine Kinases metabolism
Abstract

The precise development of the neocortex is a prerequisite for higher cognitive and associative functions. Despite numerous advances that have been made in understanding neuronal differentiation and cortex development, our knowledge regarding the impact of specific genes associated with neurodevelopmental disorders on these processes is still limited. Here, we show that Taok2, which is encoded in humans within the autism spectrum disorder (ASD) susceptibility locus 16p11.2, is essential for neuronal migration. Overexpression of de novo mutations or rare variants from ASD patients disrupts neuronal migration in an isoform-specific manner. The mutated TAOK2α variants but not the TAOK2β variants impaired neuronal migration. Moreover, the TAOK2α isoform colocalizes with microtubules. Consequently, neurons lacking Taok2 have unstable microtubules with reduced levels of acetylated tubulin and phosphorylated JNK1. Mice lacking Taok2 develop gross cortical and cortex layering abnormalities. Moreover, acute Taok2 downregulation or Taok2 knockout delayed the migration of upper-layer cortical neurons in mice, and the expression of a constitutively active form of JNK1 rescued these neuronal migration defects. Finally, we report that the brains of the Taok2 KO and 16p11.2 del Het mouse models show striking anatomical similarities and that the heterozygous 16p11.2 microdeletion mouse model displayed reduced levels of phosphorylated JNK1 and neuronal migration deficits, which were ameliorated upon the introduction of TAOK2α in cortical neurons and in the developing cortex of those mice. These results delineate the critical role of TAOK2 in cortical development and its contribution to neurodevelopmental disorders, including ASD., (© 2022. The Author(s).)

Published
2022
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