131. Targeted Genome Editing in Spinal Muscular Atrophy

Spinal muscular atrophy (SMA) is an autosomal recessive neuromuscular disorder caused by mutations in the survival-motor-neuron 1 (SMN1) telomeric gene. Deficiencies in the ubiquitous SMN function affect multiple tissues and organs; however neuronal tissue is primarily sensitive, resulting in α-motor neuron degeneration in the ventral horn of the spinal cord with subsequent neuromuscular-junction dysfunction and proximal muscle weakness. The onset of disease and degree of severity are variable in patients and they are determined in part by multiple copies of the centromeric homologue SMN2 that inversely correlate with the phenotypic severity. Indeed, SMN2 gene mainly produces a truncated form SMNΔ7 by aberrant alternative splicing and a small amount (~10%) of the fully active full-length SMN, thus buffering the SMN deficiency. A potential strategy for treating SMA patients is to increase SMN levels in the affected tissues, hence gene therapy and modifiers of SMN2-alternative splicing have proved therapeutic efficacy in SMA animal models.In this study, we explored the possibility of applying targeted genome editing technology to the human SMN locus in order to revert the SMN2 sequence to a SMN1-like sequence that may undergo proper splicing under the the endogenous transcriptional control. The resulting correction would be permanent and lead to longlasting protein production in gene-edited cells. We used the streptococcus pyogenes Cas9-CRISPR system to target the SMN2 gene at different locations. Two main strategies were explored: i) SMN1_exon7 addition/correction by promoting homology-driven DNA repair, ii) SMN2_intron7_ intronic-splicing-silencer (ISS-N1)mutation and correction of SMN2 aberrant splicing, by exploiting the non-homologous end-joining (NHEJ) pathway. Plasmids encoding Cas9-GFP under the control of CMV promoter, and selected gRNAs downstream to the Pol-III U6 promoter (Addgene) were transfected in HEK-293T cell line and in immortalized myoblasts derived from either healthy donors or SMA patients. Transfection efficiency was estimated as percentage of GFP-expressing cells (20-50% and 1-10%, respectively) and nuclease activity detected by Surveyor assay and target site sequencing. In particular, in SMA patient-derived myoblasts we detected mutations (indels) at the level of the induced DNA double-strand break at ~30% frequency. Levels of SMN restoration will be investigated by qPCR of the different species of SMN transcripts and by western blotting of SMN protein. The goal of this study is to provide an in vitro proof of principle of effective gene correction in SMA patient-derived cells. In the context of a multisystemic, complicated disease such as SMA, targeted genome editing strategy could represent an additional therapeutic tool

Rapid, comprehensive analysis of the dystrophin transcript by a custom micro-fluidic exome array

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Macrophages: A minimally invasive tool for monitoring collagen VI myopathies

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C6orf10 low-frequency and rare variants in italian multiple sclerosis patients

In light of the complex nature of multiple sclerosis (MS) and the recently estimated contribution of low-frequency variants into disease, decoding its genetic risk components requires novel variant prioritization strategies. We selected, by reviewing MS Genome Wide Association Studies (GWAS), 107 candidate loci marked by intragenic single nucleotide polymorphisms (SNPs) with a remarkable association (p-value <= 5 x 10(-6)). A whole exome sequencing (WES)-based pilot study of SNPs with minor allele frequency (MAF) <= 0.04, conducted in three Italian families, revealed 15 exonic low-frequency SNPs with affected parent-child transmission. These variants were detected in 65/120 Italian unrelated MS patients, also in combination (22 patients). Compared with databases (controls gnomAD, dbSNP150, ExAC, Tuscany-1000 Genome), the allelic frequencies of C6orf10 rs 16870005 and IL2RA rs12722600 were significantly higher (i.e., controls gnomAD, p = 9.89 x 10(-7) and p < 1 x 10(-20)). TET2 rs61744960 and TRAF3 rs138943371 frequencies were also significantly higher, except in Tuscany-1000 Genome. Interestingly, the association of C6orf10 rs16870005 (Ala431Thr) with MS did not depend on its linkage disequilibrium with the HLA-DRB1 locus. Sequencing in the MS cohort of the C6orf10 3' region revealed 14 rare mutations (10 not previously reported). Four variants were null, and significantly more frequent than in the databases. Further, the C6orf10 rare variants were observed in combinations, both intra-locus and with other low-frequency SNPs. The C6orf10 Ser389Xfr was found homozygous in a patient with early onset of the MS. Taking into account the potentially functional impact of the identified exonic variants, their expression in combination at the protein level could provide functional insights in the heterogeneous pathogenetic mechanisms contributing to MS.In light of the complex nature of multiple sclerosis (MS) and the recently estimated contribution of low-frequency variants into disease, decoding its genetic risk components requires novel variant prioritization strategies. We selected, by reviewing MS Genome Wide Association Studies (GWAS), 107 candidate loci marked by intragenic single nucleotide polymorphisms (SNPs) with a remarkable association (p-value ≤ 5 × 10−6). A whole exome sequencing (WES)-based pilot study of SNPs with minor allele frequency (MAF) ≤ 0.04, conducted in three Italian families, revealed 15 exonic low-frequency SNPs with affected parent-child transmission. These variants were detected in 65/120 Italian unrelated MS patients, also in combination (22 patients). Compared with databases (controls gnomAD, dbSNP150, ExAC, Tuscany-1000 Genome), the allelic frequencies of C6orf10 rs16870005 and IL2RA rs12722600 were significantly higher (i.e., controls gnomAD, p = 9.89 × 10−7 and p < 1 × 10−20). TET2 rs61744960 and TRAF3 rs138943371 frequencies were also significantly higher, except in Tuscany-1000 Genome. Interestingly, the association of C6orf10 rs16870005 (Ala431Thr) with MS did not depend on its linkage disequilibrium with the HLA-DRB1 locus. Sequencing in the MS cohort of the C6orf10 3′ region revealed 14 rare mutations (10 not previously reported). Four variants were null, and significantly more frequent than in the databases. Further, the C6orf10 rare variants were observed in combinations, both intra-locus and with other low-frequency SNPs. The C6orf10 Ser389Xfr was found homozygous in a patient with early onset of the MS. Taking into account the potentially functional impact of the identified exonic variants, their expression in combination at the protein level could provide functional insights in the heterogeneous pathogenetic mechanisms contributing to MS

Exon Skipping-Mediated Dystrophin Reading Frame Restoration for Small Mutations

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A novel custom high density-comparative genomic hybridization array detects common rearrangements as well as deep intronic mutations in dystrophinopathies

<p>Abstract</p> <p>Background</p> <p>The commonest pathogenic <it>DMD </it>changes are intragenic deletions/duplications which make up to 78% of all cases and point mutations (roughly 20%) detectable through direct sequencing. The remaining mutations (about 2%) are thought to be pure intronic rearrangements/mutations or 5'-3' UTR changes. In order to screen the huge <it>DMD </it>gene for all types of copy number variation mutations we designed a novel custom high density comparative genomic hybridisation array which contains the full genomic region of the <it>DMD </it>gene and spans from 100 kb upstream to 100 kb downstream of the 2.2 Mb <it>DMD </it>gene.</p> <p>Results</p> <p>We studied 12 DMD/BMD patients who either had no detectable mutations or carried previously identified quantitative pathogenic changes in the <it>DMD </it>gene. We validated the array on patients with previously known mutations as well as unaffected controls, we identified three novel pure intronic rearrangements and we defined all the mutation breakpoints both in the introns and in the 3' UTR region. We also detected a novel polymorphic intron 2 deletion/duplication variation. Despite the high resolution of this approach, RNA studies were required to confirm the functional significance of the intronic mutations identified by CGH. In addition, RNA analysis identified three intronic pathogenic variations affecting splicing which had not been detected by the CGH analysis.</p> <p>Conclusion</p> <p>This novel technology represents an effective high throughput tool to identify both common and rarer DMD rearrangements. RNA studies are required in order to validate the significance of the CGH array findings. The combination of these tools will fully cover the identification of causative DMD rearrangements in both coding and non-coding regions, particularly in patients in whom standard although extensive techniques are unable to detect a mutation.</p

Identification of a deep intronic mutation in the COL6A2 gene by a novel custom oligonucleotide CGH array designed to explore allelic and genetic heterogeneity in collagen VI-related myopathies

BACKGROUND: Molecular characterization of collagen-VI related myopathies currently relies on standard sequencing, which yields a detection rate approximating 75-79% in Ullrich congenital muscular dystrophy (UCMD) and 60-65% in Bethlem myopathy (BM) patients as PCR-based techniques tend to miss gross genomic rearrangements as well as copy number variations (CNVs) in both the coding sequence and intronic regions. METHODS: We have designed a custom oligonucleotide CGH array in order to investigate the presence of CNVs in the coding and non-coding regions of COL6A1, A2, A3, A5 and A6 genes and a group of genes functionally related to collagen VI. A cohort of 12 patients with UCMD/BM negative at sequencing analysis and 2 subjects carrying a single COL6 mutation whose clinical phenotype was not explicable by inheritance were selected and the occurrence of allelic and genetic heterogeneity explored. RESULTS: A deletion within intron 1A of the COL6A2 gene, occurring in compound heterozygosity with a small deletion in exon 28, previously detected by routine sequencing, was identified in a BM patient. RNA studies showed monoallelic transcription of the COL6A2 gene, thus elucidating the functional effect of the intronic deletion. No pathogenic mutations were identified in the remaining analyzed patients, either within COL6A genes, or in genes functionally related to collagen VI. CONCLUSIONS: Our custom CGH array may represent a useful complementary diagnostic tool, especially in recessive forms of the disease, when only one mutant allele is detected by standard sequencing. The intronic deletion we identified represents the first example of a pure intronic mutation in COL6A genes

Custom CGH array profiling of copy number variations (CNVs) on chromosome 6p21.32 (HLA locus) in patients with venous malformations associated with multiple sclerosis

<p>Abstract</p> <p>Background</p> <p>Multiple sclerosis (MS) is a complex disorder thought to result from an interaction between environmental and genetic predisposing factors which have not yet been characterised, although it is known to be associated with the HLA region on 6p21.32. Recently, a picture of chronic cerebrospinal venous insufficiency (CCSVI), consequent to stenosing venous malformation of the main extra-cranial outflow routes (VM), has been described in patients affected with MS, introducing an additional phenotype with possible pathogenic significance.</p> <p>Methods</p> <p>In order to explore the presence of copy number variations (CNVs) within the HLA locus, a custom CGH array was designed to cover 7 Mb of the HLA locus region (6,899,999 bp; chr6:29,900,001-36,800,000). Genomic DNA of the 15 patients with CCSVI/VM and MS was hybridised in duplicate.</p> <p>Results</p> <p>In total, 322 CNVs, of which 225 were extragenic and 97 intragenic, were identified in 15 patients. 234 known polymorphic CNVs were detected, the majority of these being situated in non-coding or extragenic regions. The overall number of CNVs (both extra- and intragenic) showed a robust and significant correlation with the number of stenosing VMs (Spearman: r = 0.6590, p = 0.0104; linear regression analysis r = 0.6577, p = 0.0106).</p> <p>The region we analysed contains 211 known genes. By using pathway analysis focused on angiogenesis and venous development, MS, and immunity, we tentatively highlight several genes as possible susceptibility factor candidates involved in this peculiar phenotype.</p> <p>Conclusions</p> <p>The CNVs contained in the HLA locus region in patients with the novel phenotype of CCSVI/VM and MS were mapped in detail, demonstrating a significant correlation between the number of known CNVs found in the HLA region and the number of CCSVI-VMs identified in patients. Pathway analysis revealed common routes of interaction of several of the genes involved in angiogenesis and immunity contained within this region. Despite the small sample size in this pilot study, it does suggest that the number of multiple polymorphic CNVs in the HLA locus deserves further study, owing to their possible involvement in susceptibility to this novel MS/VM plus phenotype, and perhaps even other types of the disease.</p

Correction of duplications in the DMD gene by a CRISPR/Cas9 approach

The long term goal of this project is to generate the first therapeutic approach for tandem exon duplications. The selected target will be the most frequent duplication in the dystrophin gene (DMD): exon 2 duplication. In order to open the way to a therapy for this class of neglected variations we will develop viral vectors to test the efficacy of the approach in in vitro models. In detail, we will: 1) assemble CRISPR/Cas9 systems to target the DMD gene exon 2 duplication: the system will target an intronic portion of the duplicated region so that it will create two double strand breaks and stimulate the repair machinery to recombine these sites leading to the exclusion of the duplication; 2) deliver CRISPR/Cas9 systems in HEK293 and myogenic cells to identify the more efficient one; 3) produce immortalized myogenic cells from fibroblasts of patients with exon 2 duplications as cellular models for testing our therapeutic approach; 4) develop Adeno-Associated Virus (AAV) vectors for the delivery of the selected CRISPR/Cas9 systems in the myogenic cells derived from fibroblasts of patients with exon 2 duplication and characterize the resulting effect. This proposal will evaluate the feasibility of a gene targeting approach to rescue the exon 2 duplication which results in a DMD phenotype. Overall these objectives will provide the proof-of-principle for a therapeutic approach for duplications paving the way for the treatment of several other diseases