Genomic sequencing of a dyslexia susceptibility haplotype encompassing ROBO1

Background: The DYX5 locus for developmental dyslexia was mapped to chromosome 3 by linkage study of a large Finnish family, and later, roundabout guidance receptor 1 (ROBO1) was implicated as a candidate gene at DYX5 with suppressed expression from the segregating rare haplotype. A functional magnetoencephalographic study of several family members revealed abnormal auditory processing of interaural interaction, supporting a defect in midline crossing of auditory pathways. In the current study, we have characterized genetic variation in the broad ROBO1 gene region in the DYX5-linked family, aiming to identify variants that would increase our understanding of the altered expression of ROBO1. Methods: We have used a whole genome sequencing strategy on a pooled sample of 19 individuals in combination with two individually sequenced genomes. The discovered genetic variants were annotated and filtered. Subsequently, the most interesting variants were functionally tested using relevant methods, including electrophoretic mobility shift assay (EMSA), luciferase assay, and gene knockdown by lentiviral small hairpin RNA (shRNA) in lymphoblasts. Results: We found one novel intronic single nucleotide variant (SNV) and three novel intergenic SNVs in the broad region of ROBO1 that were specific to the dyslexia susceptibility haplotype. Functional testing by EMSA did not support the binding of transcription factors to three of the SNVs, but one of the SNVs was bound by the LIM homeobox 2 (LHX2) protein, with increased binding affinity for the non-reference allele. Knockdown of LHX2 in lymphoblast cell lines extracted from subjects from the DYX5-linked family showed decreasing expression of ROBO1, supporting the idea that LHX2 regulates ROBO1 also in human. Conclusions: The discovered variants may explain the segregation of dyslexia in this family, but the effect appears subtle in the experimental settings. Their impact on the developing human brain remains suggestive based on the association and subtle experimental support.Peer reviewe

The Zebrafish Orthologue of the Dyslexia Candidate Gene DYX1C1 Is Essential for Cilia Growth and Function

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Rare variants in dynein heavy chain genes in two individuals with situs inversus and developmental dyslexia : a case report

Background Developmental dyslexia (DD) is a neurodevelopmental learning disorder with high heritability. A number of candidate susceptibility genes have been identified, some of which are linked to the function of the cilium, an organelle regulating left-right asymmetry development in the embryo. Furthermore, it has been suggested that disrupted left-right asymmetry of the brain may play a role in neurodevelopmental disorders such as DD. However, it is unknown whether there is a common genetic cause to DD and laterality defects or ciliopathies. Case presentation Here, we studied two individuals with co-occurring situs inversus (SI) and DD using whole genome sequencing to identify genetic variants of importance for DD and SI. Individual 1 had primary ciliary dyskinesia (PCD), a rare, autosomal recessive disorder with oto-sino-pulmonary phenotype and SI. We identified two rare nonsynonymous variants in the dynein axonemal heavy chain 5 gene (DNAH5): a previously reported variant c.7502G > C; p.(R2501P), and a novel variant c.12043 T > G; p.(Y4015D). Both variants are predicted to be damaging. Ultrastructural analysis of the cilia revealed a lack of outer dynein arms and normal inner dynein arms. MRI of the brain revealed no significant abnormalities. Individual 2 had non-syndromic SI and DD. In individual 2, one rare variant (c.9110A > G;p.(H3037R)) in the dynein axonemal heavy chain 11 gene (DNAH11), coding for another component of the outer dynein arm, was identified. Conclusions We identified the likely genetic cause of SI and PCD in one individual, and a possibly significant heterozygosity in the other, both involving dynein genes. Given the present evidence, it is unclear if the identified variants also predispose to DD and further studies into the association between laterality, ciliopathies and DD are needed.Peer reviewe

Ciliary dyslexia candidate genes DYX1C1 and DCDC2 are regulated by Regulatory Factor X (RFX) transcription factors through X-box promoter motifs

DYX1C1, DCDC2, and KIAA0319 are three of the most replicated dyslexia candidate genes (DCGs). Recently, these DCGs were implicated in functions at the cilium. Here, we investigate the regulation of these DCGs by Regulatory Factor X transcription factors (RFX TFs), a gene family known for transcriptionally regulating ciliary genes. We identify conserved X-box motifs in the promoter regions of DYX1C1, DCDC2, and KIAA0319 and demonstrate their functionality, as well as the ability to recruit RFX TFs using reporter gene and electrophoretic mobility shift assays. Furthermore, we uncover a complex regulation pattern between RFX1, RFX2, and RFX3 and their significant effect on modifying the endogenous expression of DYX1C1 and DCDC2 in a human retinal pigmented epithelial cell line immortalized with hTERT (hTERT-RPE1). In addition, induction of ciliogenesis increases the expression of RFX TFs and DCGs. At the protein level, we show that endogenous DYX1C1 localizes to the base of the cilium, whereas DCDC2 localizes along the entire axoneme of the cilium, thereby validating earlier localization studies using overexpression models. Our results corroborate the emerging role of DCGs in ciliary function and characterize functional noncoding elements, X-box promoter motifs, in DCG promoter regions, which thus can be targeted for mutation screening in dyslexia and ciliopathies associated with these genes.Peer reviewe

Essential role of the N-terminal region of TFII-I in viability and behavior

<p>Abstract</p> <p>Background</p> <p><it>GTF2I </it>codes for a general intrinsic transcription factor and calcium channel regulator TFII-I, with high and ubiquitous expression, and a strong candidate for involvement in the morphological and neuro-developmental anomalies of the Williams-Beuren syndrome (WBS). WBS is a genetic disorder due to a recurring deletion of about 1,55-1,83 Mb containing 25-28 genes in chromosome band 7q11.23 including <it>GTF2I</it>. Completed homozygous loss of either the <it>Gtf2i </it>or <it>Gtf2ird1 </it>function in mice provided additional evidence for the involvement of both genes in the craniofacial and cognitive phenotype. Unfortunately nothing is now about the behavioral characterization of heterozygous mice.</p> <p>Methods</p> <p>By gene targeting we have generated a mutant mice with a deletion of the first 140 amino-acids of TFII-I. mRNA and protein expression analysis were used to document the effect of the study deletion. We performed behavioral characterization of heterozygous mutant mice to document <it>in vivo </it>implications of TFII-I in the cognitive profile of WBS patients.</p> <p>Results</p> <p>Homozygous and heterozygous mutant mice exhibit craniofacial alterations, most clearly represented in homozygous condition. Behavioral test demonstrate that heterozygous mutant mice exhibit some neurobehavioral alterations and hyperacusis or odynacusis that could be associated with specific features of WBS phenotype. Homozygous mutant mice present highly compromised embryonic viability and fertility. Regarding cellular model, we documented a retarded growth in heterozygous MEFs respect to homozygous or wild-type MEFs.</p> <p>Conclusion</p> <p>Our data confirm that, although additive effects of haploinsufficiency at several genes may contribute to the full craniofacial or neurocognitive features of WBS, correct expression of <it>GTF2I </it>is one of the main players. In addition, these findings show that the deletion of the fist 140 amino-acids of TFII-I altered it correct function leading to a clear phenotype, at both levels, at the cellular model and at the <it>in vivo </it>model.</p

Robust estimation of bacterial cell count from optical density

Optical density (OD) is widely used to estimate the density of cells in liquid culture, but cannot be compared between instruments without a standardized calibration protocol and is challenging to relate to actual cell count. We address this with an interlaboratory study comparing three simple, low-cost, and highly accessible OD calibration protocols across 244 laboratories, applied to eight strains of constitutive GFP-expressing E. coli. Based on our results, we recommend calibrating OD to estimated cell count using serial dilution of silica microspheres, which produces highly precise calibration (95.5% of residuals &lt;1.2-fold), is easily assessed for quality control, also assesses instrument effective linear range, and can be combined with fluorescence calibration to obtain units of Molecules of Equivalent Fluorescein (MEFL) per cell, allowing direct comparison and data fusion with flow cytometry measurements: in our study, fluorescence per cell measurements showed only a 1.07-fold mean difference between plate reader and flow cytometry data

Characterization of human chromosome 22 : Cloning of breakpoints of the constitutional translocation t(11;22)(q23;q11) and detection of small constitutional delections by microarray CGH

Chromosome 22 is the second smallest human chromosome, composing approximately 1.5% of the genome. The short arm of this acrocentric chromosome harbors ribosomal genes and the long arm contains the protein coding genes. This chromosome is gene-rich in comparison to the majority of other chromosomes, containing approximately 600 so far characterized genes. Many of these are involved in the etiology of a wide spectrum of diseases such as congenital and psychiatric disorders as well as cancers. The constitutional translocation t(11;22) is the most common reciprocal translocation in humans. This translocation is often found in families but can also occur de novo. Translocation carriers are normal and usually become diagnosed in connection with infertility problems or a birth of a genetically unbalanced child. In addition, an increased risk to breast cancer has been reported in some carriers, which suggests that the translocation might have an effect on a gene(s) involved in the etiology of breast cancer. We characterized the breakpoints of this translocation and found that the breakpoint region on chromosome 22 lies within an unclonable gap. The breakpoint on chromosome 11 is also located within an unstable region, as all BACs containing this segment are rearranged. We identified one BAC from chromosome 11 spanning the translocation breakpoint and two BAC clones from chromosome 22, which contain sequences similar/identical to the sequences mediating the translocations breakpoints on chromosome 22. A cosmid library from one translocation carrier was also constructed and chimeric cosmids from both derivative chromosomes were isolated. Their analysis revealed that no gene(s) seems to be disrupted by the translocation breakpoints. We also show that the breakpoints on both chromosomes occur at the tip of hairpins, which are formed due to the presence of long inverted repeats/palindromes. The formation of these structures is the likely reason behind "unclonability" of this region on chromosome 22 and the instability of BACs derived from chromosome 11. Furthermore, based on fiber-FISH experiments we conclude that the breakpoints of the translocations are highly conserved among carriers. The second aspect of the thesis is related to detection of micro-deletions and micro- gains, which cause a large number of genetic disorders. In order to improve the detection of such rearrangements, we applied and further developed the microarray-CGH methodology. We constructed three microarrays: one covering 7 Mb region in the vicinity of the NF2 gene in 22q12; the second is a full coverage chromosome 22 array; and the third is an array covering 6 Mb from the 22q11 region, including the typically deleted region in DiGeorgeVelo-Cardio-Facial syndrome. The latter region is particularly challenging, due to the presence of low copy repeats, high content of common repeats and unclonable sequences. Three types of targets were used in the arrays: i) genomic clones; ii) non-redundant, repeatfree pools of genomic DNA amplified by PCR; and iii) cDNA-based targets, single as well as in pools. We used the arrays to study neurofibromatosis type 2, acral melanoma, dermatofibrosarcoma, and DiGeorge/Velo-Cardio-Facial syndrome. We were able to detect homozygous/heterozygous deletions, amplifications, IGLV/IGLC locus instability and the breakpoints of an imbalanced translocation. Using the novel approach with repeat-free, PCRgenerated sequences, we detected heterozygous deletions using as little as 11.5 kb of genomic target sequence. We conclude that the array-CGH is a powerful method for the detection of gene-dosage imbalances. Our results also suggest that most, if not all, medically important segments of our genome will be accessible for analysis using high-resolution microarraybased CGH

Genetic and protein interaction studies between the ciliary dyslexia candidate genes DYX1C1 and DCDC2

BackgroundDYX1C1 (DNAAF4) and DCDC2 are two of the most replicated dyslexia candidate genes in genetic studies. They both have demonstrated roles in neuronal migration, in cilia growth and function and they both are cytoskeletal interactors. In addition, they both have been characterized as ciliopathy genes. However, their exact molecular functions are still incompletely described. Based on these known roles, we asked whether DYX1C1 and DCDC2 interact on the genetic and the protein level.ResultsHere, we report the physical protein-protein interaction of DYX1C1 and DCDC2 as well as their respective interactions with the centrosomal protein CPAP (CENPJ) on exogenous and endogenous levels in different cell models including brain organoids. In addition, we show a synergistic genetic interaction between dyx1c1 and dcdc2b in zebrafish exacerbating the ciliary phenotype. Finally, we show a mutual effect on transcriptional regulation among DYX1C1 and DCDC2 in a cellular model.ConclusionsIn summary, we describe the physical and functional interaction between the two genes DYX1C1 and DCDC2. These results contribute to the growing understanding of the molecular roles of DYX1C1 and DCDC2 and set the stage for future functional studies.Peer reviewe