ABSTRACT
We identified individuals with variations in ACTL6B, a component of the chromatin remodeling machinery including the BAF complex. Ten individuals harbored bi-allelic mutations and presented with global developmental delay, epileptic encephalopathy, and spasticity, and ten individuals with de novo heterozygous mutations displayed intellectual disability, ambulation deficits, severe language impairment, hypotonia, Rett-like stereotypies, and minor facial dysmorphisms (wide mouth, diastema, bulbous nose). Nine of these ten unrelated individuals had the identical de novo c.1027G>A (p.Gly343Arg) mutation. Human-derived neurons were generated that recaptured ACTL6B expression patterns in development from progenitor cell to post-mitotic neuron, validating the use of this model. Engineered knock-out of ACTL6B in wild-type human neurons resulted in profound deficits in dendrite development, a result recapitulated in two individuals with different bi-allelic mutations, and reversed on clonal genetic repair or exogenous expression of ACTL6B. Whole-transcriptome analyses and whole-genomic profiling of the BAF complex in wild-type and bi-allelic mutant ACTL6B neural progenitor cells and neurons revealed increased genomic binding of the BAF complex in ACTL6B mutants, with corresponding transcriptional changes in several genes including TPPP and FSCN1, suggesting that altered regulation of some cytoskeletal genes contribute to altered dendrite development. Assessment of bi-alleic and heterozygous ACTL6B mutations on an ACTL6B knock-out human background demonstrated that bi-allelic mutations mimic engineered deletion deficits while heterozygous mutations do not, suggesting that the former are loss of function and the latter are gain of function. These results reveal a role for ACTL6B in neurodevelopment and implicate another component of chromatin remodeling machinery in brain disease.
Subject(s)
Actins/genetics , Chromosomal Proteins, Non-Histone/genetics , DNA-Binding Proteins/genetics , Dendrites/pathology , Epilepsy/etiology , Induced Pluripotent Stem Cells/pathology , Mutation , Neurodevelopmental Disorders/etiology , Neurons/pathology , Adult , Child , Child, Preschool , Chromatin/genetics , Chromatin/metabolism , Dendrites/metabolism , Epilepsy/pathology , Female , Humans , Induced Pluripotent Stem Cells/metabolism , Infant , Male , Neurodevelopmental Disorders/pathology , Neurons/metabolism , Young AdultABSTRACT
We performed whole-genome sequencing on an individual from a family with variable psychiatric phenotypes that had a sensory processing disorder, apraxia, and autism. The proband harbored a maternally inherited balanced translocation (46,XY,t(11;14)(p12;p12)mat) that disrupted LRRC4C, a member of the highly specialized netrin G family of axon guidance molecules. The proband also inherited a paternally derived chromosomal inversion that disrupted DPP6, a potassium channel interacting protein. Copy Number (CN) analysis in 14,077 cases with neurodevelopmental disorders and 8,960 control subjects revealed that 60% of cases with exonic deletions in LRRC4C had a second clinically recognizable syndrome associated with variable clinical phenotypes, including 16p11.2, 1q44, and 2q33.1 CN syndromes, suggesting LRRC4C deletion variants may be modifiers of neurodevelopmental disorders. In vitro, functional assessments modeling patient deletions in LRRC4C suggest a negative regulatory role of these exons found in the untranslated region of LRRC4C, which has a single, terminal coding exon. These data suggest that the proband's autism may be due to the inheritance of disruptions in both DPP6 and LRRC4C, and may highlight the importance of the netrin G family and potassium channel interacting molecules in neurodevelopmental disorders. © 2016 Wiley Periodicals, Inc.
Subject(s)
Dipeptidyl-Peptidases and Tripeptidyl-Peptidases/genetics , Genetic Association Studies , Nerve Tissue Proteins/genetics , Neurodevelopmental Disorders/diagnosis , Neurodevelopmental Disorders/genetics , Phenotype , Potassium Channels/genetics , Receptors, Cell Surface/genetics , 5' Untranslated Regions , Adolescent , Adult , Apraxias/diagnosis , Apraxias/genetics , Autistic Disorder/diagnosis , Autistic Disorder/genetics , Child , Child, Preschool , Chromosome Breakpoints , Chromosome Inversion , Comparative Genomic Hybridization , DNA Copy Number Variations , Female , Gene Expression , Gene Expression Profiling , High-Throughput Nucleotide Sequencing , Humans , Karyotype , Male , Middle Aged , Multigene Family , Pedigree , Translocation, Genetic , Young AdultABSTRACT
Mutations in HPRT1, a gene encoding a rate-limiting enzyme for purine salvage, cause Lesch-Nyhan disease which is characterized by self-injury and motor impairments. We leveraged stem cell and genetic engineering technologies to model the disease in isogenic and patient-derived forebrain and midbrain cell types. Dopaminergic progenitor cells deficient in HPRT showed decreased intensity of all developmental cell-fate markers measured. Metabolic analyses revealed significant loss of all purine derivatives, except hypoxanthine, and impaired glycolysis and oxidative phosphorylation. real-time glucose tracing demonstrated increased shunting to the pentose phosphate pathway for de novo purine synthesis at the expense of ATP production. Purine depletion in dopaminergic progenitor cells resulted in loss of RHEB, impairing mTORC1 activation. These data demonstrate dopaminergic-specific effects of purine salvage deficiency and unexpectedly reveal that dopaminergic progenitor cells are programmed to a high-energy state prior to higher energy demands of terminally differentiated cells.
Subject(s)
Dopaminergic Neurons/metabolism , Energy Metabolism , Lesch-Nyhan Syndrome/metabolism , Lesch-Nyhan Syndrome/pathology , Mesencephalon/pathology , Biomarkers/metabolism , Cell Lineage , Cerebral Cortex/pathology , Glucose/metabolism , Glycolysis , Humans , Hypoxanthine Phosphoribosyltransferase/deficiency , Lesch-Nyhan Syndrome/enzymology , Mechanistic Target of Rapamycin Complex 1/metabolism , Neural Stem Cells/metabolism , Oxidative Phosphorylation , Pentose Phosphate Pathway , Purines/metabolismABSTRACT
The development of targeted therapeutics for rare neurodevelopmental disorders (NDDs) faces significant challenges due to the scarcity of subjects and the difficulty of obtaining human neural cells. Here, we illustrate a rapid, simple protocol by which patient derived cells can be reprogrammed to induced pluripotent stem cells (iPSCs) using an episomal vector and differentiated into neurons. Using this platform enables patient somatic cells to be converted to physiologically active neurons in less than two months with minimal labor. This platform includes a method to combine somatic cell reprogramming with CRISPR/Cas9 gene editing at single cell resolution, which enables the concurrent development of clonal knockout or knock-in models that can be used as isogenic control lines. This platform reduces the logistical barrier for using iPSC technology, allows for the development of appropriate control lines for use in rare neurodevelopmental disease research, and establishes a fundamental component to targeted therapeutics and precision medicine. Stem Cells Translational Medicine 2017;6:886-896.
Subject(s)
CRISPR-Associated Protein 9/metabolism , CRISPR-Cas Systems/genetics , Gene Editing , Models, Biological , Neurodevelopmental Disorders/pathology , Base Sequence , Cell Differentiation , Fibroblasts/pathology , Humans , Induced Pluripotent Stem Cells/metabolism , Mesencephalon/pathology , Neurons/pathology , Prosencephalon/pathologyABSTRACT
Lesch-Nyhan syndrome (LNS) is a rare X-linked disorder caused by mutations in HPRT1, an important enzyme in the purine salvage pathway. Symptoms of LNS include dystonia, gout, intellectual disability, and self-mutilation. Despite having been characterized over 50 years ago, it remains unclear precisely how deficits in hypoxanthine and guanine recycling can lead to such a profound neurological phenotype. Several studies have proposed different hypotheses regarding the etiology of this disease, and several treatments have been tried in patients, though none have led to a satisfactory explanation of the disease. New technologies such as next-generation sequencing, optogenetics, genome editing, and induced pluripotent stem cells provide a unique opportunity to map the precise sequential pathways leading from genotype to phenotype.