Positive Association of Vitamin D Receptor Gene Variations with Multiple Sclerosis in South East Iranian Population

Among the factors postulated to play a role in MS susceptibility, the role of vitamin D is outstanding. Since the function of vitamin D receptor (VDR) represents the effect of vitamin D on the body and genetic variations in VDR gene may affect its function, we aim to highlight the association of two VDR gene polymorphisms with MS susceptibility. In current study, we recruited 113 MS patients and 122 healthy controls. TaqI (rs731236) and ApaI (rs7975232) genetic variations in these two groups were evaluated using the polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) technique. All genotype and allele frequencies in both variations showed association with the disease status. However, to find the definite connection between genetic variations in VDR gene and MS disease in a population of South East of Iran, more researches on gene structure and its function with regard to patients’ conditions are required

© 2009 Molecular Vision Genotyping results of Iranian PCG families suggests one or more PCG locus other than GCL3A, GCL3B, and GCL3C exist

Purpose: To assess whether loci other than GLC3A, GLC3B, and GLC3C are linked to primary congenital glaucom

SVEP1 as a Genetic Modifier of TEK-Related Primary Congenital Glaucoma

PURPOSE. Affecting children by age 3, primary congenital glaucoma (PCG) can cause debilitating vision loss by the developmental impairment of aqueous drainage resulting in high intraocular pressure (IOP), globe enlargement, and optic neuropathy. TEK haploinsufficiency accounts for 5% of PCG in diverse populations, with low penetrance explained by variable dysgenesis of Schlemm’s canal (SC) in mice. We report eight families with TEK-related PCG, and provide evidence for SVEP1 as a disease modifier in family 8 with a higher penetrance and severity. METHODS. Exome sequencing identified coding/splice site variants with an allele frequency less than 0.0001 (gnomAD). TEK variant effects were assayed in constructtransfected HEK293 cells via detection of autophosphorylated (active) TEK protein. An enucleated eye from an affected member of family 8 was examined via histology. SVEP1 expression in developing outflow tissues was detected by immunofluorescent staining of 7-day mouse anterior segments. SVEP1 stimulation of TEK expression in human umbilical vascular endothelial cells (HUVECs) was measured by TaqMan quantitative PCR. RESULTS. Heterozygous TEK loss-of-function alleles were identified in eight PCG families, with parent–child disease transmission observed in two pedigrees. Family 8 exhibited greater disease penetrance and severity, histology revealed absence of SC in one eye, and SVEP1:p.R997C was identified in four of the five affected individuals. During SC development, SVEP1 is secreted by surrounding tissues. SVEP1:p.R997C abrogates stimulation of TEK expression by HUVECs. CONCLUSIONS. We provide further evidence for PCG caused by TEK haploinsufficiency, affirm autosomal dominant inheritance in two pedigrees, and propose SVEP1 as a modifier of TEK expression during SC development, affecting disease penetrance and severity.Supported by the National Institutes of Health [R01EY014685 to T.Y., R01HL124120, T32DK108738, R01EY025799, and P30DK114857 to S.Q.]; the Research to Prevent Blindness Inc. [Lew R. Wasserman Award to T.Y.]; a University of Wisconsin Centennial Scholars Award [to T.Y.]; the Flinders Foundation and the National Health and Medical Research Council of Australia [APP1116360, APP1107098, and fellowship APP1154824 to J.C.]; the Foundation for Science and Technology, Human Potential Operational Program/European Social Fund [fellowship SFRH/BD/90445/2012 to S.C.]; the Agency for Science Technology and Research, under the Industry Alignment Fund - Pre-Positioning Programme, as part of the Innovations in Food & Chemical Safety Programme [H18/01/a0/b14 to V.L.]; the Ophthalmic Research Center of Shahid Beheshti University of Medical Sciences and the Iran National Science Foundation [940012 to E.E.]; a Core Grant for Vision Research from the National Eye Institute/National Institutes of Health to the University of Wisconsin-Madison [P30EY016665]; and an Unrestricted Grant from Research to Prevent Blindness, Inc. to the UW-Madison Department of Ophthalmology and Visual Sciences. The authors are grateful to the Vanderbilt clinical site of the Undiagnosed Diseases Network for contribution of one individual for this manuscript: John A Phillips III, John H. Newman, Joy Cogan, and Rizwan Hamid; supported in part by the National Institutes of Health Common Fund [UO1HG007674]