Global increases in both common and rare copy number load associated with autism.

Children with autism have an elevated frequency of large, rare copy number variants (CNVs). However, the global load of deletions or duplications, per se, and their size, location and relationship to clinical manifestations of autism have not been documented. We examined CNV data from 516 individuals with autism or typical development from the population-based Childhood Autism Risks from Genetics and Environment (CHARGE) study. We interrogated 120 regions flanked by segmental duplications (genomic hotspots) for events >50 kbp and the entire genomic backbone for variants >300 kbp using a custom targeted DNA microarray. This analysis was complemented by a separate study of five highly dynamic hotspots associated with autism or developmental delay syndromes, using a finely tiled array platform (>1 kbp) in 142 children matched for gender and ethnicity. In both studies, a significant increase in the number of base pairs of duplication, but not deletion, was associated with autism. Significantly elevated levels of CNV load remained after the removal of rare and likely pathogenic events. Further, the entire CNV load detected with the finely tiled array was contributed by common variants. The impact of this variation was assessed by examining the correlation of clinical outcomes with CNV load. The level of personal and social skills, measured by Vineland Adaptive Behavior Scales, negatively correlated (Spearman's r = -0.13, P = 0.034) with the duplication CNV load for the affected children; the strongest association was found for communication (P = 0.048) and socialization (P = 0.022) scores. We propose that CNV load, predominantly increased genomic base pairs of duplication, predisposes to autism

Disruption of RFX family transcription factors causes autism, attention-deficit/hyperactivity disorder, intellectual disability, and dysregulated behavior

Purpose We describe a novel neurobehavioral phenotype of autism spectrum disorder (ASD), intellectual disability, and/or attention-deficit/hyperactivity disorder (ADHD) associated with de novo or inherited deleterious variants in members of the RFX family of genes. RFX genes are evolutionarily conserved transcription factors that act as master regulators of central nervous system development and ciliogenesis. Methods We assembled a cohort of 38 individuals (from 33 unrelated families) with de novo variants in RFX3, RFX4, and RFX7. We describe their common clinical phenotypes and present bioinformatic analyses of expression patterns and downstream targets of these genes as they relate to other neurodevelopmental risk genes. Results These individuals share neurobehavioral features including ASD, intellectual disability, and/or ADHD; other frequent features include hypersensitivity to sensory stimuli and sleep problems. RFX3, RFX4, and RFX7 are strongly expressed in developing and adult human brain, and X-box binding motifs as well as RFX ChIP-seq peaks are enriched in the cis-regulatory regions of known ASD risk genes. Conclusion These results establish a likely role of deleterious variation in RFX3, RFX4, and RFX7 in cases of monogenic intellectual disability, ADHD and ASD, and position these genes as potentially critical transcriptional regulators of neurobiological pathways associated with neurodevelopmental disease pathogenesis

Genetic studies of two inherited human phenotypes : Hearing loss and monoamine oxidase activity

This thesis focuses on the identification of genetic factors underlying two inherited human phenotypes: hearing loss and monoamine oxidase activity. Non-syndromic hearing loss segregating in a Swedish family was tested for linkage to 13 previously reported candidate loci for hearing disabilities. Linkage was found to two loci: DFNA12 (llq22-q24) and DFNA2 (lp32). A detailed analysis of the phenotypes and haplotypes shared by the affected individuals supported the hypothesis of digenic inheritance of hearing disability in the Swedish family. Mutation screening of α-tectorin, a gene residing within the DFNA12 region revealed a mutation of a conserved amino acid (Cys to Ser), that segregated with the disease. The identification of the mutation added support to the involvement of α-tectorin in hearing disabilities. In contrast, no mutations were identified in two candidate genes at the DFNA2 locus, that were reported to cause hearing loss in other families. It is possible that the DFNA2 locus contains a third, not yet identified, hearing loss gene. Monoamine oxidase A (MAOA) and B (MAOB) catalyze the degradation of certain neurotransmitters in the central nervous system and are associated with specific behavioral and neuropsychiatric human traits. Activity levels of both monoamine oxidases (MAO) are highly variable among humans and are determined by unknown genetic factors. This study investigated the relationship of different MAO alleles with MAO mRNA levels and enzyme activity in human brain. Several novel DNA polymorphisms were identified in a group of Swedish individuals. Haplotypes containing several closely located MAOA polymorphisms were assessed in Asian, African, and Caucasian populations. The haplotype distribution and diversity pattern found among the three populations supported the occurrence of a bottleneck during the dispersion of modem humans from Africa. Allelic association studies conducted on postmortem human brain samples, revealed the association between a SNP in the MAOB intron 13, and different levels of both MAO enzyme activities. This suggested that this SNP is in linkage disequilibrium with at least one novel functional DNA polymorphism that controls MAO enzyme activities in human brain. The identification of functional polymorphisms regulating the activity of these enzymes will help to elucidate the involvement of MAO in human behavior and neuropsychiatric conditions

Genetic studies of two inherited human phenotypes : Hearing loss and monoamine oxidase activity

This thesis focuses on the identification of genetic factors underlying two inherited human phenotypes: hearing loss and monoamine oxidase activity. Non-syndromic hearing loss segregating in a Swedish family was tested for linkage to 13 previously reported candidate loci for hearing disabilities. Linkage was found to two loci: DFNA12 (llq22-q24) and DFNA2 (lp32). A detailed analysis of the phenotypes and haplotypes shared by the affected individuals supported the hypothesis of digenic inheritance of hearing disability in the Swedish family. Mutation screening of α-tectorin, a gene residing within the DFNA12 region revealed a mutation of a conserved amino acid (Cys to Ser), that segregated with the disease. The identification of the mutation added support to the involvement of α-tectorin in hearing disabilities. In contrast, no mutations were identified in two candidate genes at the DFNA2 locus, that were reported to cause hearing loss in other families. It is possible that the DFNA2 locus contains a third, not yet identified, hearing loss gene. Monoamine oxidase A (MAOA) and B (MAOB) catalyze the degradation of certain neurotransmitters in the central nervous system and are associated with specific behavioral and neuropsychiatric human traits. Activity levels of both monoamine oxidases (MAO) are highly variable among humans and are determined by unknown genetic factors. This study investigated the relationship of different MAO alleles with MAO mRNA levels and enzyme activity in human brain. Several novel DNA polymorphisms were identified in a group of Swedish individuals. Haplotypes containing several closely located MAOA polymorphisms were assessed in Asian, African, and Caucasian populations. The haplotype distribution and diversity pattern found among the three populations supported the occurrence of a bottleneck during the dispersion of modem humans from Africa. Allelic association studies conducted on postmortem human brain samples, revealed the association between a SNP in the MAOB intron 13, and different levels of both MAO enzyme activities. This suggested that this SNP is in linkage disequilibrium with at least one novel functional DNA polymorphism that controls MAO enzyme activities in human brain. The identification of functional polymorphisms regulating the activity of these enzymes will help to elucidate the involvement of MAO in human behavior and neuropsychiatric conditions

Gene trapping using Gal4 in zebrafish

Large clutch size and external development of optically transparent embryos make zebrafish an exceptional vertebrate model system for in vivo insertional mutagenesis using fluorescent reporters to tag expression of mutated genes. Several laboratories have constructed and tested enhancer- and gene-trap vectors in zebrafish, using fluorescent proteins, Gal4- and lexA- based transcriptional activators as reporters 1-7. These vectors had two potential drawbacks: suboptimal stringency (e.g. lack of ability to differentiate between enhancer- and gene-trap events) and low mutagenicity (e.g. integrations into genes rarely produced null alleles). Gene Breaking Transposon (GBTs) were developed to address these drawbacks 8-10. We have modified one of the first GBT vectors, GBT-R15, for use with Gal4-VP16 as the primary gene trap reporter and added UAS:eGFP as the secondary reporter for direct detection of gene trap events. Application of Gal4-VP16 as the primary gene trap reporter provides two main advantages. First, it increases sensitivity for genes expressed at low expression levels. Second, it enables researchers to use gene trap lines as Gal4 drivers to direct expression of other transgenes in very specific tissues. This is especially pertinent for genes with non-essential or redundant functions, where gene trap integration may not result in overt phenotypes. The disadvantage of using Gal4-VP16 as the primary gene trap reporter is that genes coding for proteins with N-terminal signal sequences are not amenable to trapping, as the resulting Gal4-VP16 fusion proteins are unlikely to be able to enter the nucleus and activate transcription. Importantly, the use of Gal4-VP16 does not pre-select for nuclear proteins: we recovered gene trap mutations in genes encoding proteins which function in the nucleus, the cytoplasm and the plasma membrane

Mice Mutant in the DM Domain Gene Dmrt4 Are Viable and Fertile but Have Polyovular Follicles

Proteins containing the DM domain, a zinc finger-like DNA binding motif, have been implicated in sexual differentiation in diverse metazoan organisms. Of seven mammalian DM domain genes, only Dmrt1 and Dmrt2 have been functionally analyzed. Here, we report expression analysis and targeted disruption of Dmrt4 (also called DmrtA1) in the mouse. Dmrt4 is widely expressed during embryonic and postnatal development. However, we find that mice homozygous for a putative null mutation in Dmrt4 develop essentially normally, undergo full sexual differentiation in both sexes, and are fertile. We observed two potential mutant phenotypes in Dmrt4 mutant mice. First, ovaries of most mutant females have polyovular follicles, suggesting a role in folliculogenesis. Second, 25% of mutant males consistently exhibited copulatory behavior toward other males. We also tested potential redundancy between Dmrt4 and two other gonadally expressed DM domain genes, Dmrt1 and Dmrt7. We observed no enhancement of gonadal phenotypes in the double mutants, suggesting that these genes function independently in gonadal development

Tol2-based On/Off/On (“Switchblade”, GBT-S1/S8) vectors for insertional mutagenesis and characterized gene trap lines.

<p><b>A.</b> Diagram of the vector and conditional regulation. The gene trap cassette is flanked by lox71, FRT-10, FRT+10 and lox66 sites. Components responsible for high degree of mutagenicity are shown in red. SA, carp beta actin splice acceptor, ^Gal-VP16, AUG-less Gal4-VP16, zp(A), zebrafish beta actin 3’ UTR and transcriptional termination sequences, cry, <i>X</i>. <i>laevis</i> gamma crystalline promoter, p(A), SV40 poly(A). The gene trap cassette is identical to that used in GBT-B1 gene trap vector (Balciuniene et al., 2013). Expression Flp recombinase will result in inversion of the gene trap cassette and one wild type (FRT) and one double mutant, inactive (FRT+10/-10, two red dots) site. Expression of the Cre recombinase will result in second inversion of the cassette conditionally mutating the gene. <b>B.</b> GBT-S1 and GBT-S8 gene trap lines. First column, gene trap line. Second column, sequence adjacent to the 3’ end of the gene trap integration. The capital CTG are the last three nucleotides of Tol2. Third column, location of the gene trap integration on the GRCz10 zebrafish genome assembly. Fourth column, insertionally mutated gene (IMG). Fifth column, sequence of the IMG-Gal4-VP16 fusion protein, IMG sequence is highlighted in aqua, Gal4 sequence is highlighted in magenta. The “linker” sequence is encoded by the linker between splice acceptor and Gal4 in GBT-S1 and GBT-S8. <b>C.</b> Diagram of gene trap loci. Gene trap integration site is shown as a triangle, with mutated gene’s exons depicted as squares: grey for non-coding, black for 5’ of integration site and white for 3’ of integration site. <b>D.</b> Assessment of transcript levels by quantitative RT-PCR. Three non-phenotypic lines were chosen for analysis. Quantitative RT PCR was performed on pools of RNA from wild type and homozygous mutant 5 dpf embryos, and normalized to beta actin. Error bars represent standard deviation.</p