Understanding the impact of ZBTB18 missense variation on transcription factor function in neurodevelopment and disease

Understanding the impact of ZBTB18 missense variation on transcription factor function in neurodevelopment and disease

Mutations to genes that encode DNA‐binding transcription factors (TFs) underlie a broad spectrum of human neurodevelopmental disorders. Here, we highlight the pathological mechanisms arising from mutations to TF genes that influence the development of mammalian cerebral cortex neurons. Drawing on re...

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Bibliographic Details
Published in:Journal of neurochemistry Vol. 161; no. 3; pp. 219 - 235
Main Authors: Heng, Julian I.‐T., Viti, Leon, Pugh, Kye, Marshall, Owen J., Agostino, Mark
Format: Journal Article
Language:English
Published: England Blackwell Publishing Ltd 01-05-2022
John Wiley and Sons Inc
Subjects:
Abnormalities
Anatomy
Animals
Biological effects
Brain
Brain architecture
brain disorder
Cerebral cortex
Cortex (temporal)
Deoxyribonucleic acid
DNA
DNA‐binding
Gene Expression Regulation
Gene regulation
Genes
Homeostasis
Humans
Mammals - metabolism
Missense mutation
missense variation
Mutation
Mutation, Missense - genetics
Neurodevelopment
Neurodevelopmental disorders
neuronal development
Neurons
Neurons - metabolism
Review
Reviews
transcription factor
Transcription factors
Transcription Factors - genetics
Transcription Factors - metabolism
Variation
neuronal development
cerebral cortex
transcription factor
missense variation
brain disorder
DNA-binding
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Summary:Mutations to genes that encode DNA‐binding transcription factors (TFs) underlie a broad spectrum of human neurodevelopmental disorders. Here, we highlight the pathological mechanisms arising from mutations to TF genes that influence the development of mammalian cerebral cortex neurons. Drawing on recent findings for TF genes including ZBTB18, we discuss how functional missense mutations to such genes confer non‐native gene regulatory actions in developing neurons, leading to cell‐morphological defects, neuroanatomical abnormalities during foetal brain development and functional impairment. Further, we discuss how missense variation to human TF genes documented in the general population endow quantifiable changes to transcriptional regulation, with potential cell biological effects on the temporal progression of cerebral cortex neuron development and homeostasis. We offer a systematic approach to investigate the functional impact of missense variation in brain TFs and define their direct molecular and cellular actions in foetal neurodevelopment, tissue homeostasis and disease states. In this Review article, we discuss the functions for several transcription factors (TFs) in mammalian neural circuit development and provide a theoretical framework for the functional categorization of missense variants to TF genes based upon their impact on gene regulatory activities, which we define as TF co‐operation, competition and combination signaling. Drawing on studies of ZBTB18, we outline a systematic approach to investigate the functional impact of disease‐causing missense variants, as well as modifier alleles (Categories 0 to 3, as shown), that directly disrupt neural circuit development and neuronal homeostasis.
Bibliography:Funding informationCurtin Research Fellowship CRF130006 and Raine Priming Grant to MA. National Health & Medical Research Council (Australia) Grant APP1011505 to JI‐TH and Grant APP1185220 to OM.
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ISSN:0022-3042
1471-4159
DOI:10.1111/jnc.15572