Literature DB >> 20809529

Molecular mechanisms leading to null-protein product from retinoschisin (RS1) signal-sequence mutants in X-linked retinoschisis (XLRS) disease.

Camasamudram Vijayasarathy1, Ruifang Sui, Yong Zeng, Guoxing Yang, Fei Xu, Rafael C Caruso, Richard A Lewis, Lucia Ziccardi, Paul A Sieving.   

Abstract

Retinoschisin (RS1) is a cell-surface adhesion molecule expressed by photoreceptor and bipolar cells of the retina. The 24-kDa protein encodes two conserved sequence motifs: the initial signal sequence targets the protein for secretion while the larger discoidin domain is implicated in cell adhesion. RS1 helps to maintain the structural organization of the retinal cell layers and promotes visual signal transduction. RS1 gene mutations cause X-linked retinoschisis disease (XLRS) in males, characterized by early-onset central vision loss. We analyzed the biochemical consequences of several RS1 signal-sequence mutants (c.1A>T, c.35T>A, c.38T>C, and c.52G>A) found in our subjects. Expression analysis in COS-7 cells demonstrates that these mutations affect RS1 biosynthesis and result in an RS1 null phenotype by several different mechanisms. By comparison, discoidin-domain mutations generally lead to nonfunctional conformational variants that remain trapped inside the cell. XLRS disease has a broad heterogeneity in general, but subjects with the RS1 null-protein signal-sequence mutations are on the more severe end of the clinical phenotype. Results from the signal-sequence mutants are discussed in the context of the discoidin-domain mutations, clinical phenotypes, genotype-phenotype correlations, and implications for RS1 gene replacement therapy. This article is a US Government work and, as such, is in the public domain in the United States of America. Published in 2010 by Wiley-Liss, Inc.

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Year:  2010        PMID: 20809529      PMCID: PMC2991635          DOI: 10.1002/humu.21350

Source DB:  PubMed          Journal:  Hum Mutat        ISSN: 1059-7794            Impact factor:   4.878


  62 in total

Review 1.  Pre-mRNA splicing and human disease.

Authors:  Nuno André Faustino; Thomas A Cooper
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2.  Intracellular retention of mutant retinoschisin is the pathological mechanism underlying X-linked retinoschisis.

Authors:  Tao Wang; Caroline T Waters; Alex M K Rothman; Tracy J Jakins; Karin Römisch; Dorothy Trump
Journal:  Hum Mol Genet       Date:  2002-11-15       Impact factor: 6.150

3.  Novel mutations in XLRS1 causing retinoschisis, including first evidence of putative leader sequence change.

Authors:  K T Hiriyanna; E L Bingham; B M Yashar; R Ayyagari; G Fishman; K W Small; D V Weinberg; R G Weleber; R A Lewis; S Andreasson; J E Richards; P A Sieving
Journal:  Hum Mutat       Date:  1999       Impact factor: 4.878

4.  Analysis of photoreceptor function and inner retinal activity in juvenile X-linked retinoschisis.

Authors:  N W Khan; J A Jamison; J A Kemp; P A Sieving
Journal:  Vision Res       Date:  2001-12       Impact factor: 1.886

5.  Phenotypic expression of juvenile X-linked retinoschisis in Swedish families with different mutations in the XLRS1 gene.

Authors:  L C Eksandh; V Ponjavic; R Ayyagari; E L Bingham; K T Hiriyanna; S Andréasson; B Ehinger; P A Sieving
Journal:  Arch Ophthalmol       Date:  2000-08

6.  Clinical characteristics of 14 japanese patients with X-linked juvenile retinoschisis associated with XLRS1 mutation.

Authors:  K Shinoda; S Ishida; Y Oguchi; Y Mashima
Journal:  Ophthalmic Genet       Date:  2000-09       Impact factor: 1.803

Review 7.  Emerging links between initiation of translation and human diseases.

Authors:  Marilyn Kozak
Journal:  Mamm Genome       Date:  2002-08       Impact factor: 2.957

8.  Defective discoidin domain structure, subunit assembly, and endoplasmic reticulum processing of retinoschisin are primary mechanisms responsible for X-linked retinoschisis.

Authors:  Winco W H Wu; Robert S Molday
Journal:  J Biol Chem       Date:  2003-05-13       Impact factor: 5.157

9.  Molecular modeling of retinoschisin with functional analysis of pathogenic mutations from human X-linked retinoschisis.

Authors:  Y V Sergeev; R C Caruso; M R Meltzer; N Smaoui; I M MacDonald; P A Sieving
Journal:  Hum Mol Genet       Date:  2010-01-08       Impact factor: 6.150

10.  Mutations of the XLRS1 gene cause abnormalities of photoreceptor as well as inner retinal responses of the ERG.

Authors:  K Bradshaw; N George; A Moore; D Trump
Journal:  Doc Ophthalmol       Date:  1999       Impact factor: 1.854
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  20 in total

1.  Retinal AAV8-RS1 Gene Therapy for X-Linked Retinoschisis: Initial Findings from a Phase I/IIa Trial by Intravitreal Delivery.

Authors:  Catherine Cukras; Henry E Wiley; Brett G Jeffrey; H Nida Sen; Amy Turriff; Yong Zeng; Camasamudram Vijayasarathy; Dario Marangoni; Lucia Ziccardi; Sten Kjellstrom; Tae Kwon Park; Suja Hiriyanna; J Fraser Wright; Peter Colosi; Zhijian Wu; Ronald A Bush; Lisa L Wei; Paul A Sieving
Journal:  Mol Ther       Date:  2018-07-07       Impact factor: 11.454

2.  A novel deletion mutation in RS1 gene caused X-linked juvenile retinoschisis in a Chinese family.

Authors:  Y Huang; L Mei; B Gui; W Su; D Liang; L Wu; Q Pan
Journal:  Eye (Lond)       Date:  2014-08-29       Impact factor: 3.775

Review 3.  X-linked juvenile retinoschisis: clinical diagnosis, genetic analysis, and molecular mechanisms.

Authors:  Robert S Molday; Ulrich Kellner; Bernhard H F Weber
Journal:  Prog Retin Eye Res       Date:  2012-01-03       Impact factor: 21.198

4.  Enamel malformations associated with a defined dentin sialophosphoprotein mutation in two families.

Authors:  Shih-Kai Wang; Hui-Chen Chan; Sudha Rajderkar; Rachel N Milkovich; Karen A Uston; Jung-Wook Kim; James P Simmer; Jan C-C Hu
Journal:  Eur J Oral Sci       Date:  2011-12       Impact factor: 2.612

5.  Phenotypic expression of X-linked retinoschisis in Chinese families with mutations in the RS1 gene.

Authors:  Fei Xu; Hang Xiang; Ruxin Jiang; Fangtian Dong; Ruifang Sui
Journal:  Doc Ophthalmol       Date:  2011-06-24       Impact factor: 2.379

Review 6.  Biology of retinoschisin.

Authors:  Camasamudram Vijayasarathy; Lucia Ziccardi; Paul A Sieving
Journal:  Adv Exp Med Biol       Date:  2012       Impact factor: 2.622

7.  Variation in genes controlling warfarin disposition and response in American Indian and Alaska Native people: CYP2C9, VKORC1, CYP4F2, CYP4F11, GGCX.

Authors:  Alison E Fohner; Renee Robinson; Joseph Yracheta; Denise A Dillard; Brian Schilling; Burhan Khan; Scarlett Hopkins; Bert Boyer; Jynene Black; Howard Wiener; Hemant K Tiwari; Adam Gordon; Deborah Nickerson; Jesse M Tsai; Federico M Farin; Timothy A Thornton; Allan E Rettie; Kenneth E Thummel
Journal:  Pharmacogenet Genomics       Date:  2015-07       Impact factor: 2.089

8.  Preclinical Dose-Escalation Study of Intravitreal AAV-RS1 Gene Therapy in a Mouse Model of X-linked Retinoschisis: Dose-Dependent Expression and Improved Retinal Structure and Function.

Authors:  Ronald A Bush; Yong Zeng; Peter Colosi; Sten Kjellstrom; Suja Hiriyanna; Camasamudram Vijayasarathy; Maria Santos; Jinbo Li; Zhijian Wu; Paul A Sieving
Journal:  Hum Gene Ther       Date:  2016-05       Impact factor: 5.695

9.  Paired octamer rings of retinoschisin suggest a junctional model for cell-cell adhesion in the retina.

Authors:  Gökhan Tolun; Camasamudram Vijayasarathy; Rick Huang; Yong Zeng; Yan Li; Alasdair C Steven; Paul A Sieving; J Bernard Heymann
Journal:  Proc Natl Acad Sci U S A       Date:  2016-04-25       Impact factor: 11.205

10.  Molecular modeling indicates distinct classes of missense variants with mild and severe XLRS phenotypes.

Authors:  Yuri V Sergeev; Susan Vitale; Paul A Sieving; Ajoy Vincent; Anthony G Robson; Anthony T Moore; Andrew R Webster; Graham E Holder
Journal:  Hum Mol Genet       Date:  2013-07-11       Impact factor: 6.150
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