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Study of ophthalmo acromelic syndromes in human and mouseRainger, Joe January 2009 (has links)
The combination of severe ocular and distal limb malformations is rare. Ophthalmo-acromelic syndrome (OAS; MIM 206920) is characterised by anophthalmia with lower limb oligodactyly. To date <40 cases of this autosomal recessive disorder have been reported. Genome-wide analysis of ~10,000 SNPs typed on two apparently unrelated families - comprising a total of three affected individuals, four unaffected siblings and their consanguineous parents - identified a large region of overlapping autozygosity on chromosome 14q. Adding data from a third consanguineous family gave a combined LOD score of >5 with no evidence of locus heterogeneity. Collaborative data from a further 6 individuals refined the critical interval to a 3.4 Mb region on chromosome14:69,652,605-73,059,612 Mb. To sequence all 19 known protein-coding genes in the region, the 238 exons were ranked by evolutionary sequence conservation and divided equally between the Edinburgh and Nijmegen groups. Complete sequence coverage has been obtained for 61% of the “Edinburgh” exons but no potentially causative mutations have been identified. Further mutation analysis of the OAS locus is on-going. Mice homozygous for the X-ray induced Mp mutation were reportedly anophthalmic with hind limb oligodactyly and thus represented a potential model for human OAS. This line was rederived in Edinburgh and phenotypic analysis of Mp/Mp homozygotes showed runting, malformed pinnae with microphthalmia but not anophthalmia. The apparent hind-limb oligodactyly was due to osseous syndactyly. Mp heterozygotes had milder microphthalmia and pinnae deformities, but lacked the syndactyly. In both heterozygotes and homozygotes the eye malformations were fully penetrant, pan-ocular and characterised by failure of both the ciliary apparatus and vitreous body to form and abnormal retinal lamination. Genome-wide microsatellite marker analysis showed linkage of the Mp phenotype to chromosome 18. Fbn2 mapped within the linkage interval and was a good candidate for Mp based on the finding of hind limb osseous syndactyly in Fbn2-null mice. However, Fbn2-null mice have no eye phenotype. 3’-RACE identified that Mp was as a 660 kb inversion affecting the 3’-regions of Fbn2 and the adjacent gene Isoc1. This created two aberrant reciprocal fusion transcripts: Fbn2 exons 1-63 are fused to Isoc1 exon 5; and Isoc1 exons 1-4 are fused to Fbn2 exons 64-65. This predicts nonsense-mediated decay of the Isoc1 Mp transcript and production of a truncated Fbn2 Mp protein. Ocular development was analysed in homozygote and wild type embryos to define the basis of the “worse than null phenotype” seen in Mp mice. RNA in situ hybridisations (ISH) failed to detect expression of Isoc1 in the embryonic eye. In contrast, normal expression of Fbn2 in the ciliary body and retina was consistent with the Mp phenotype. A combination of EM and immunocytochemistry showed that truncated Fbn2 (Fbn2Mp) was retained within the ER. Fbn2Mp co-localised with markers of ER stress: Grp78 expression and UPR-specific Xbp1 splicing. Signalling by Wnt2b is thought to be critical for ciliary development and Lef1, a Wnt-responsive transcription factor, showed increased and ectopic ocular expression in the region affected by ER stress. Sox2 is a direct transcriptional target of Lef1 and we observed apparent ectopic expression of Sox2 in the ciliary body. Throughout the developing retina in mutant embryos we also observed individual cells that were ectopically expressing the transcription factor Chx10 and other cells expressing the apoptotic marker Activated- Caspase-3. The apoptotic marker did not specifically co-localise with Fbn2Mp. Taken together, these findings suggest that the ocular malformations in Mp are a direct result of the ER stress induced by Fbn2Mp in a specific group of cells in the early ciliary body. The ER stress presumably halts post-translational modification of a developmentally critical signaling molecule, possibly Wnt2b, which happens to be expressed in the same cells. We have termed the resulting pathological mechanism a synodiporic effect (synodiporia = the ones walking the street together or fellow travellers). Such effects may have significant implications for human genetic disease analysis, and may provide an explanation for other “worse than null” mutations.
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Investigating the functional role of SMOC-1 in zebrafishSexton, David James January 2016 (has links)
True anophthalmia is the most severe congenital eye malformation. With absence of the eye, optic nerve, chiasm and optic tracts. Identifying the genes that cause genetic true anophthalmia should improve our understanding of the critical processes required for development of the eye. Recessive loss-of-function mutations in SMOC1 have been identified as the cause of Ophthalmo-acromelic syndrome (OAS), a multisystem disorder which has true anophthalmia as a prominent feature with characteristic limb and facial malformations. In order to establish the function of SMOC1 in development I used the zebrafish as a model organism to support a link between SMOC-1 and BMP signalling. As a first step I characterised the genomic structure of zebrafish smoc1 gene. I was able to correct an error in the zebrafish genome (Zv8) that annotated zsmoc1 as two fragmented and rearranged orthologous loci. However, using RTPCR I could show that there is in fact a single intact zsmoc1 transcript. In addition, I was able to identify an un-annotated 5’ coding exon using 5' RACE which showed that the full open reading frame includes a signalling peptide. RT-PCR was also used to identify several novel zsmoc1 splice isoforms. To explore the link between zsmoc1 and bmp signalling I used injection of antisense morpholino oligonucleotide and capped mRNA to examine the effects of loss-of-function and overexpression respectively of smoc1 and genes functioning in the bmp signalling pathway. The resulting embryos were analysed using morphometric analysis (Kishimoto scale), a quantitative assay of dorsalisation/ventralisation and live imaging of reporter transgenic fish. I developed a quantitative RT-PCR assay for expression of dorsal (otx2 and runx3) and ventral (eve1 and gata2) marker genes. I established a reliable system for live imaging of zebrafish development between 8 hpf and 24 hpf. By combining this system with fluorescent transgenic reporters marking the eye field (rx3:gfp reporter) and BMP-signaling (BRE:gfp reporter) I was able to accurately quantitate the effect of smoc1 depletion on eye size and SMAD1/5/8 signalling in the eye. These results support the predictions from the Drosophila homologue Pent that zsmoc1 functions as an antagonist of bmp signalling. Finally, I describe my attempt to produce a zebrafish model for OAS using genome editing technology. I designed, produced and validated transcription activator like effectors nucleases (TALENs) targeted to the zsmoc1 open reading frame using the Voytas Goldengate method. I designed and optimised a novel strategy to demonstrate targeted cutting activity for in vitro validation. Following injections of the in vitro validated TALEN into zebrafish embryos I used Ion Torrent sequencing to assess the in vivo activity of the engineered TALEN pairs. Unfortunately these TALENs were not able to cut the targeted locus in vivo.
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