Your search keyword '"OPN1LW"' showing total 75 results

1. Blue cone monochromacy and gene therapy

Author

Sechrest, Emily R., Chmelik, Kathryn, Tan, Wendy D., and Deng, Wen-Tao

Published

2023

2. Opsin 3-GαS Promotes Airway Smooth Muscle Relaxation Modulated by G Protein Receptor Kinase 2.

Author

Wu, Amy D., Dan, William, Yi Zhang, Vemaraju, Shruti, Upton, Brian A., Lang, Richard A., Buhr, Ethan D., Berkowitz, Dan E., Gallos, George, Emala, Charles W., and Yim, Peter D.

Subjects

OPSINS, G protein-coupled receptor kinases, MUSCLE contraction, ANIMAL models in research, BLUE light

Abstract

Recently, we characterized blue light--mediated relaxation (photorelaxation) of airway smooth muscle (ASM) and implicated the involvement of opsin 3 (OPN3), an atypical opsin. In the present study, we characterized the cellular signaling mechanisms of photorelaxation. We confirmed the functional role of OPN3 in blue light photorelaxation using trachea from OPN3 null mice (maximal relaxation 52 ± 13% compared with wild-type mice 90 ± 4.3%, P < 0.05). We then demonstrated colocalization of OPN3 and Gαs using co-IP and proximity ligation assays in primary human ASM cells, which was further supported by an increase in cAMP in mouse trachea treated with blue light compared with dark controls (23 ± 3.6 vs. 14 ± 2.6 pmol cAMP/ring, P < 0.05). Downstream PKA (protein kinase A) involvement was shown by inhibiting photorelaxation using Rp-cAMPS (P < 0.0001). Moreover, we observed converging mechanisms of desensitization by chronic β2-agonist exposure in mouse trachea and correlated this finding with colocalization of OPN3 and GRK2 (G protein receptor kinase) in primary human ASM cells. Finally, an overexpression model of OPN1LW (a red light photoreceptor in the same opsin family) in human ASM cells showed an increase in intracellular cAMP levels following red light exposure compared with nontransfected cells (48 ± 13 vs. 13 ± 2.1 pmol cAMP/mg protein, P < 0.01), suggesting a conserved photorelaxation mechanism for wavelengths of light that are more tissue penetrant. Together, these results demonstrate that blue light photorelaxation in ASM is mediated by the OPN3 receptor interacting with Gαs, which increases cAMP levels, activating PKA and modulated by GRK2. [ABSTRACT FROM AUTHOR]

Published

2021

3. OPN1LW and OPN1MW

Author

Zahid, Sarwar, Branham, Kari, Schlegel, Dana, Pennesi, Mark E., Michaelides, Michel, Heckenlively, John, Jayasundera, Thiran, Zahid, Sarwar, Branham, Kari, Schlegel, Dana, Pennesi, Mark E., Michaelides, Michel, Heckenlively, John, and Jayasundera, Thiran

Published

2018

4. Colour vision variation in leaf‐nosed bats (Phyllostomidae): Links to cave roosting and dietary specialization.

Author

Kries, Kelly, Barros, Marília A. S., Duytschaever, Gwen, Orkin, Joseph D., Janiak, Mareike C., Pessoa, Daniel M. A., and Melin, Amanda D.

Subjects

*NUCLEOTIDE sequence, *PHYLLOSTOMIDAE, *ROOSTING, *CHEMICAL industry, *PSEUDOGENES, *CHARTS, diagrams, etc.

Abstract

Abstract: Bats are a diverse radiation of mammals of enduring interest for understanding the evolution of sensory specialization. Colour vision variation among species has previously been linked to roosting preferences and echolocation form in the suborder Yinpterochiroptera, yet questions remain about the roles of diet and habitat in shaping bat visual ecology. We sequenced OPN1SW and OPN1LW opsin genes for 20 species of leaf‐nosed bats (family Phyllostomidae; suborder Yangochiroptera) with diverse roosting and dietary ecologies, along with one vespertilionid species (Myotis lavali). OPN1LW genes appear intact for all species, and predicted spectral tuning of long‐wavelength opsins varied among lineages. OPN1SW genes appear intact and under purifying selection for Myotis lavali and most phyllostomid bats, with two exceptions: (a) We found evidence of ancient OPN1SW pseudogenization in the vampire bat lineage, and loss‐of‐function mutations in all three species of extant vampire bats; (b) we additionally found a recent, independently derived OPN1SW pseudogene in Lonchophylla mordax, a cave‐roosting species. These mutations in leaf‐nosed bats are independent of the OPN1SW pseudogenization events previously reported in Yinpterochiropterans. Therefore, the evolution of monochromacy (complete colour blindness) has occurred in both suborders of bats and under various evolutionary drivers; we find independent support for the hypothesis that obligate cave roosting drives colour vision loss. We additionally suggest that haematophagous dietary specialization and corresponding selection on nonvisual senses led to loss of colour vision through evolutionary sensory trade‐off. Our results underscore the evolutionary plasticity of opsins among nocturnal mammals. [ABSTRACT FROM AUTHOR]

Published

2018

5. Visual and ocular findings in a family with X-linked cone dysfunction and protanopia

Author

Dag Holmquist, Bernd Wissinger, Jürg Hengstler, David Epstein, Susanne Kohl, Kristina Tear-Fahnehjelm, and Monica Olsson

Subjects

Male, medicine.medical_specialty, Visual acuity, Adolescent, genetic structures, Color vision, Visual Acuity, Color Vision Defects, Amblyopia, Retina, Young Adult, Exon, chemistry.chemical_compound, Sickness Impact Profile, Ophthalmology, Electroretinography, Myopia, medicine, Humans, Genetics (clinical), Color Perception Tests, medicine.diagnostic_test, business.industry, Rod Opsins, Genetic Diseases, X-Linked, Retinal, Exons, eye diseases, Phenotype, chemistry, OPN1LW, Myopia, Degenerative, Pediatrics, Perinatology and Child Health, sense organs, Visual Fields, medicine.symptom, Protanopia, business, Erg, Color Perception, Tomography, Optical Coherence

Abstract

Background: Bornholm eye disease (BED) is a rare X-linked cone dysfunction disorder with high myopia, amblyopia, and color vision defects.Materials and methods: Visual and ocular outcomes in a family where two of five siblings had molecularly confirmed BED are reported. Ophthalmological assessments included best-corrected visual acuity (BCVA), color vision test, and optical coherence tomography (OCT). Medical records, electroretinography (ERG), and genetic analyses were re-evaluated.Results: Two male siblings had confirmed BED with myopia and protanopia. The younger brother had high myopia, subnormal BCVA, and ocular fundi that showed tilted discs, crescent shaped peripapillary atrophy, and visible choroidal vessels. OCT confirmed retinal and choroidal atrophy. The older brother was lightly myopic with normal/subnormal BCVA and subtle findings in the fundi. Both brothers had abnormal ERG recordings with a decreased cone response. They also had a structurally intact OPN1LW/OPN1MW gene cluster. The OPN1LW gene was shown to carry a deleterious variant combination in exon 3 known to result in mis-splicing of opsin mRNA and acknowledged as LIAVA amino acid delineation (Leu153-Ile171-Ala174-Val178-Ala180), while the OPN1MW gene exon 3 showed a non-pathogenic variant combination (MVVVA). Another normal-sighted brother carried another wildtype variant combination (LVAIS) in exon 3 of the OPN1LW gene.Conclusions: The two affected brothers demonstrated a large variability in their phenotypes even though the genotypes were identical. They presented a disease-associated haplotype in exon 3 of OPN1LW that has been described as the molecular cause of BED.

Published

2021

6. Gene therapy in color vision deficiency: a review

Author

Zeinab El Moussawi, Christiane Al-Haddad, and Marguerita Boueiri

Subjects

Achromatopsia, genetic structures, Color vision, Genetic enhancement, Cyclic Nucleotide-Gated Cation Channels, Color Vision Defects, Bioinformatics, 03 medical and health sciences, 0302 clinical medicine, Electroretinography, OPN1MW, medicine, Animals, Humans, GNAT2, business.industry, Genetic Therapy, medicine.disease, eye diseases, Review article, Clinical trial, Ophthalmology, OPN1LW, Mutation, Retinal Cone Photoreceptor Cells, 030221 ophthalmology & optometry, business, 030217 neurology & neurosurgery

Abstract

Color vision deficiencies are a group of vision disorders, characterized by abnormal color discrimination. They include red-green color blindness, yellow-blue color blindness and achromatopsia, among others. The deficiencies are caused by mutations in the genes coding for various components of retinal cones. Gene therapy is rising as a promising therapeutic modality. The purpose of this review article is to explore the available literature on gene therapy in the different forms of color vision deficiencies. A thorough literature review was performed on PubMed using the keywords: color vision deficiencies, gene therapy, achromatopsia and the various genes responsible for this condition (OPN1LW, OPN1MW, ATF6, CNGA3, CNGB3, GNAT2, PDE6H, and PDE6C). Various adenovirus vectors have been deployed to test the efficacy of gene therapy for achromatopsia in animals and humans. Gene therapy trials in humans and animals targeting mutations in CNGA3 have been performed, demonstrating an improvement in electroretinogram (ERG)-investigated cone cell functionality. Similar outcomes have been reported for experimental studies on other genes (CNGB3, GNAT2, M- and L-opsin). It has also been reported that delivering the genes via intravitreal rather than subretinal injections could be safer. There are currently 3 ongoing human clinical trials for the treatment of achromatopsia due to mutations in CNGB3 and CNGA3. Experimental studies and clinical trials generally showed improvement in ERG-investigated cone cell functionality and visually elicited behavior. Gene therapy is a promising novel therapeutic modality in color vision deficiencies.

Published

2021

7. Opsin 3–Gαs Promotes Airway Smooth Muscle Relaxation Modulated by G Protein Receptor Kinase 2

Author

Peter D. Yim, Yi Zhang, George Gallos, Brian A. Upton, William Dan, Ethan D. Buhr, Dan E. Berkowitz, Amy D Wu, Richard Lang, Shruti Vemaraju, and Charles W. Emala

Subjects

0301 basic medicine, Pulmonary and Respiratory Medicine, Opsin, Gs alpha subunit, genetic structures, Kinase, Chemistry, Clinical Biochemistry, Cell Biology, Airway smooth muscle, respiratory system, eye diseases, respiratory tract diseases, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, 030228 respiratory system, OPN1LW, Biophysics, Relaxation (physics), Photorelaxation, sense organs, Molecular Biology, G protein-coupled receptor

Abstract

Recently, we characterized blue light–mediated relaxation (photorelaxation) of airway smooth muscle (ASM) and implicated the involvement of opsin 3 (OPN3), an atypical opsin. In the present study, ...

Published

2021

8. Preclinical evaluation of ADVM-062, a novel intravitreal gene therapy vector for the treatment of blue cone monochromacy.

Author

Hanna K, Nieves J, Dowd C, Bender KO, Sharma P, Singh B, Renz M, Ver Hoeve JN, Cepeda D, Gelfman CM, Riley BE, and Grishanin RN

Subjects

Animals, Humans, Primates genetics, Primates metabolism, Rod Opsins genetics, Rod Opsins metabolism, Genetic Therapy methods, Retinal Cone Photoreceptor Cells metabolism, Opsins genetics

Abstract

Blue cone monochromacy (BCM) is a rare X-linked retinal disease characterized by the absence of L- and M-opsin in cone photoreceptors, considered a potential gene therapy candidate. However, most experimental ocular gene therapies utilize subretinal vector injection which would pose a risk to the fragile central retinal structure of BCM patients. Here we describe the use of ADVM-062, a vector optimized for cone-specific expression of human L-opsin and administered using a single intravitreal (IVT) injection. Pharmacological activity of ADVM-062 was established in gerbils, whose cone-rich retina naturally lacks L-opsin. A single IVT administration dose of ADVM-062 effectively transduced gerbil cone photoreceptors and produced a de novo response to long-wavelength stimuli. To identify potential first-in-human doses we evaluated ADVM-062 in non-human primates. Cone-specific expression of ADVM-062 in primates was confirmed using ADVM-062.myc, a vector engineered with the same regulatory elements as ADVM-062. Enumeration of human OPN1LW.myc-positive cones demonstrated that doses ≥3 × 10 10 vg/eye resulted in transduction of 18%-85% of foveal cones. A Good Laboratory Practice (GLP) toxicology study established that IVT administration of ADVM-062 was well tolerated at doses that could potentially achieve clinically meaningful effect, thus supporting the potential of ADVM-062 as a one-time IVT gene therapy for BCM., Competing Interests: Declaration of interests K.H., D.C., J.N., C.D., P.S., K.O.B., M.R., B.S., C.M.G., B.E.R., and R.N.G. are current or previous employees of Adverum Biotechnologies and hold stock grants. J.V.H. is a paid consultant of Adverum Biotechnologies., (Copyright © 2023 Adverum Biotechnologies Inc. Published by Elsevier Inc. All rights reserved.)

Published

2023

9. Blue Cone Monochromatism with Foveal Hypoplasia Caused by the Concomitant Effect of Variants in OPN1LW/OPN1MW and GPR143 Genes

Author

Chiara Passarelli, Luca Buzzonetti, Alessandro Cappelli, Andrea M Coppe, Antonio Novelli, Lorenzo Sinibaldi, Paolo Enrico Maltese, Sarah Cetola, and Giancarlo Iarossi

Subjects

Proband, Achromatopsia, genetic structures, QH301-705.5, Case Report, Biology, Catalysis, Inorganic Chemistry, X-linked inheritance, medicine, OPN1MW, Missense mutation, Physical and Theoretical Chemistry, Biology (General), Molecular Biology, QD1-999, Spectroscopy, X-linked recessive inheritance, OPN1LW/OPN1MW gene cluster, Organic Chemistry, blue cone monochromatism, Dystrophy, General Medicine, medicine.disease, Molecular biology, Hypoplasia, Computer Science Applications, Chemistry, OPN1LW, foveal hypoplasia, sense organs

Abstract

Blue cone monochromatism (BCM) is an X-linked recessive cone dysfunction disorder caused by mutations in the OPN1LW/OPN1MW gene cluster, encoding long (L)- and middle (M)-wavelength-sensitive cone opsins. Here, we report on the unusual clinical presentation of BCM caused by a novel mutation in the OPN1LW gene in a young man. We describe in detail the phenotype of the proband, and the subclinical morpho-functional anomalies shown by his carrier mother. At a clinical level, the extensive functional evaluation demonstrated in the proband the M/L cone affection and the sparing of S-cone function, distinctive findings of BCM. Interestingly, spectral-domain optical coherence tomography showed the presence of foveal hypoplasia with focal irregularities of the ellipsoid layer in the foveal area, reported to be associated with some cases of cone-rod dystrophy and achromatopsia. At a molecular level, we identified the novel mutation c.427T > C p.(Ser143Pro) in the OPN1LW gene and the common missense mutation c.607T > C (p.Cys203Arg) in the OPN1MW gene. In addition, we discovered the c.768-2_769delAGTT splicing variant in the GPR143 gene. To our knowledge, this is the first case of foveal hypoplasia in a BCM patient and of mild clinical affection in a female carrier caused by the concomitant effect of variants in OPN1LW/OPN1MW and GPR143 genes, thus as the result of the simultaneous action of two independent genetic defects.

Published

2021

10. Intermixing the OPN1LW and OPN1MW Genes Disrupts the Exonic Splicing Code Causing an Array of Vision Disorders

Author

Jay Neitz and Maureen Neitz

Subjects

0301 basic medicine, genetic structures, Color vision, cone photopigment, Biology, QH426-470, 03 medical and health sciences, Exon, 0302 clinical medicine, OPN1MW, medicine, Genetics, biochemistry, Photopigment, myopia, Genetics (clinical), Retina, Exon skipping, eye diseases, Cell biology, 030104 developmental biology, medicine.anatomical_structure, colorblindness, X-linked cone dysfunction, color vision, OPN1LW, RNA splicing, 030221 ophthalmology & optometry, sense organs, exon skipping

Abstract

Light absorption by photopigment molecules expressed in the photoreceptors in the retina is the first step in seeing. Two types of photoreceptors in the human retina are responsible for image formation: rods, and cones. Except at very low light levels when rods are active, all vision is based on cones. Cones mediate high acuity vision and color vision. Furthermore, they are critically important in the visual feedback mechanism that regulates refractive development of the eye during childhood. The human retina contains a mosaic of three cone types, short-wavelength (S), long-wavelength (L), and middle-wavelength (M) sensitive; however, the vast majority (~94%) are L and M cones. The OPN1LW and OPN1MW genes, located on the X-chromosome at Xq28, encode the protein component of the light-sensitive photopigments expressed in the L and M cones. Diverse haplotypes of exon 3 of the OPN1LW and OPN1MW genes arose thru unequal recombination mechanisms that have intermixed the genes. A subset of the haplotypes causes exon 3- skipping during pre-messenger RNA splicing and are associated with vision disorders. Here, we review the mechanism by which splicing defects in these genes cause vision disorders.

Published

2021

11. Three Different Cone Opsin Gene Array Mutational Mechanisms with Genotype-Phenotype Correlation and Functional Investigation of Cone Opsin Variants.

Author

Gardner, Jessica C., Liew, Gerald, Quan, Ying‐Hua, Ermetal, Burcu, Ueyama, Hisao, Davidson, Alice E., Schwarz, Nele, Kanuga, Naheed, Chana, Ravinder, Maher, Eamonn R., Webster, Andrew R., Holder, Graham E., Robson, Anthony G., Cheetham, Michael E., Liebelt, Jan, Ruddle, Jonathan B., Moore, Anthony T., Michaelides, Michel, and Hardcastle, Alison J.

Abstract

ABSTRACT Mutations in the OPN1LW ( L-) and OPN1MW ( M-)cone opsin genes underlie a spectrum of cone photoreceptor defects from stationary loss of color vision to progressive retinal degeneration. Genotypes of 22 families with a range of cone disorders were grouped into three classes: deletions of the locus control region ( LCR); missense mutation (p. Cys203 Arg) in an L-/ M-hybrid gene; and exon 3 single-nucleotide polymorphism ( SNP) interchange haplotypes in an otherwise normal gene array. Moderate-to-high myopia was observed in all mutation categories. Individuals with LCR deletions or p. Cys203 Arg mutations were more likely to have nystagmus and poor vision, with disease progression in some p. Cys203 Arg patients. Three disease-associated exon 3 SNP haplotypes encoding LIAVA, LVAVA, or MIAVA were identified in our cohort. These patients were less likely to have nystagmus but more likely to show progression, with all patients over the age of 40 years having marked macular abnormalities. Previously, the haplotype LIAVA has been shown to result in exon 3 skipping. Here, we show that haplotypes LVAVA and MIAVA also result in aberrant splicing, with a residual low level of correctly spliced cone opsin. The OPN1LW/ OPN1MW:c.532 A> G SNP, common to all three disease-associated haplotypes, appears to be principally responsible for this mutational mechanism. [ABSTRACT FROM AUTHOR]

Published

2014

12. Foveal Therapy in Blue Cone Monochromacy: Predictions of Visual Potential From Artificial Intelligence

Author

Bernd Wissinger, Samuel G. Jacobson, Susanne Kohl, Alexander Sumaroka, Rebecca Sheplock, Artur V. Cideciyan, and Vivian Wu

Subjects

0301 basic medicine, Retinal degeneration, medicine.medical_specialty, Visual acuity, visual acuity, genetic structures, Computer science, lcsh:RC321-571, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, BLUE CONE MONOCHROMACY, cones, rods, Optical coherence tomography, Foveal, Ophthalmology, medicine, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Original Research, chromatic perimetry, optical coherence tomography, medicine.diagnostic_test, General Neuroscience, Retinal, medicine.disease, eye diseases, 030104 developmental biology, machine learning, chemistry, OPN1LW, 030221 ophthalmology & optometry, Curve fitting, retinal degeneration, sense organs, medicine.symptom, random forest, Neuroscience

Abstract

Novel therapeutic approaches for treating inherited retinal degenerations (IRDs) prompt a need to understand which patients with impaired vision have the anatomical potential to gain from participation in a clinical trial. We used supervised machine learning to predict foveal function from foveal structure in blue cone monochromacy (BCM), an X-linked congenital cone photoreceptor dysfunction secondary to mutations in the OPN1LW/OPN1MW gene cluster. BCM patients with either disease-associated large deletion or missense mutations were studied and results compared with those from subjects with other forms of IRD and various degrees of preserved central structure and function. A machine learning technique was used to associate foveal sensitivities and best-corrected visual acuities to foveal structure in IRD patients. Two random forest (RF) models trained on IRD data were applied to predict foveal function in BCM. A curve fitting method was also used and results compared with those of the RF models. The BCM and IRD patients had a comparable range of foveal structure. IRD patients had peak sensitivity at the fovea. Machine learning could successfully predict foveal sensitivity (FS) results from segmented or un-segmented optical coherence tomography (OCT) input. Application of machine learning predictions to BCM at the fovea showed differences between predicted and measured sensitivities, thereby defining treatment potential. The curve fitting method provided similar results. Given a measure of visual acuity (VA) and foveal outer nuclear layer thickness, the question of how many lines of acuity would represent the best efficacious result for each BCM patient could be answered. We propose that foveal vision improvement potential in BCM is predictable from retinal structure using machine learning and curve fitting approaches. This should allow estimates of maximal efficacy in patients being considered for clinical trials and also guide decisions about dosing.

Published

2020

13. Phylogenetic analyses suggest independent origins for trichromatic color vision in apes and Old World monkeys

Author

Juan C. Opazo and Jessica Toloza-Villalobos

Subjects

Old World, biology, Phylogenetic tree, genetic structures, Evolutionary biology, OPN1LW, Color vision, biology.animal, Trichromacy, OPN1MW, Primate, Clade

Abstract

In catarrhine primates, trichromatic color vision is associated with the presence of three opsin genes that absorb light at three different wavelengths. The OPN1LW and OPN1MW genes are found on the X chromosome. Their proximity and similarity suggest that they originated from a duplication event in the catarrhine ancestor. In this study we use the primate genomes available in public databases to study the duplicative history of the OPN1LW and OPN1MW genes and characterize their spectral sensitivity. Our results reveal a phylogenetic tree that shows a clade containing all X-linked opsin paralogs found in Old World monkeys to be related to a clade containing all X-linked opsin paralogs identified in apes, suggesting that routine trichromacy originated independently in apes and Old World monkeys. Also, we found spectral variability in the X-linked opsin gene of primates. Our study presents a new perspective for the origin of trichromatic color vision in apes and Old World monkeys, not reported so far.

Published

2020

14. Causes of Color Blindness: Function and Failure of the Genes that Detect Color

Author

Taylor, Dylan and Taylor, Dylan

Abstract

Color blindness affects nearly 10% of the entire population, with multiple types of color blindness from various genetic mutations. In the following sections, the nature of light and how the human eye perceives light will be discussed. Afterward, the major forms of color blindness and their genetic causes will be considered. Once these genetic causes have been established, the current method for diagnosing color blindness will be investigated, followed by a discussion of the current treatments available to those with color blindness. Finally, a brief discussion will address possible future work for color blindness with the hope of finding better treatments and a future prevention.

Published

2020

15. Residual Cone Structure in Patients With X-Linked Cone Opsin Mutations

Author

Angelos Kalitzeos, Emily J Patterson, Jessica C. Gardner, Maureen Neitz, Jay Neitz, Melissa Kasilian, Alison J. Hardcastle, Michel Michaelides, and Joseph Carroll

Subjects

0301 basic medicine, Adult, Male, Opsin, genetic structures, Color Vision Defects, Residual, medicine.disease_cause, Retina, 03 medical and health sciences, Exon, 0302 clinical medicine, Genes, X-Linked, OPN1MW, medicine, color blindness, Humans, myopia, X-linked recessive inheritance, Mutation, Chemistry, Rod Opsins, Exons, Middle Aged, Emmetropia, Molecular biology, photoreceptor, Cone Opsins, Axial Length, Eye, 030104 developmental biology, Phenotype, Cone (topology), OPN1LW, retinal imaging, 030221 ophthalmology & optometry, Retinal Cone Photoreceptor Cells, sense organs

Abstract

Purpose To assess residual cone structure in subjects with mutations in exon 2, 3, and 4 of the OPN1LW or OPN1MW opsin. Methods Thirteen males had their OPN1LW/OPN1MW opsin genes characterized. The cone mosaic was imaged using both confocal and nonconfocal split-detection adaptive optics scanning light ophthalmoscopy (AOSLO), and retinal thickness was evaluated using optical coherence tomography (OCT). Six subjects completed serial imaging over a maximum period of 18 months and cone density was measured across imaging sessions. Results Ten subjects had an OPN1LW/OPN1MW “interchange” opsin mutation designated as LIAVA or LVAVA, which both introduce exon 3 splicing defects leading to a lack of functional photopigment in cones expressing LIAVA and greatly reduced functional photopigment in cones expressing LVAVA. Despite disrupted cone reflectivity and reduced numerosity, residual inner segments could be visualized. Similar patterns were observed in individuals with an exon 2 insertion, or an exon 4 splice defect, both of which are also expected to produce cones that are devoid of functional opsin protein. OCT revealed variably reduced retinal thickness. A significant inverse relationship was found between the proportion of waveguiding cones and axial length. Conclusions Split-detection imaging revealed that the altered appearance of the cone mosaic in confocal images for subjects with exon 2, 3, and 4 mutations was generally due to disrupted waveguiding, rather than structural loss, making them possible candidates for gene therapy to restore cone function. The relative fraction of waveguiding cones was highly variable across subjects, which appears to influence emmetropization in these subjects.

Published

2018

16. A reinterpretation of critical flicker-frequency (CFF) data reveals key details about light adaptation and normal and abnormal visual processing.

Author

Rider, Andrew T., Henning, G. Bruce, and Stockman, Andrew

Subjects

*LIGHT intensity, *PHYSIOLOGY

Abstract

Our ability to see flicker has an upper frequency limit above which flicker is invisible, known as the "critical flicker frequency" (CFF), that typically grows with light intensity (I). The relation between CFF and I, the focus of nearly 200 years of research, is roughly logarithmic, i.e., CFF ∝ log(I)-a relation called the Ferry-Porter law. However, why this law should occur, and how it relates to the underlying physiology, have never been adequately explained. Over the past two decades we have measured CFF in normal observers and in patients with retinal gene defects. Here, we reanalyse and model our data and historical CFF data. Remarkably, CFF-versus-I functions measured under a wide range of conditions in patients and in normal observers all have broadly similar shapes when plotted in double-logarithmic coordinates, i.e., log (CFF)-versus-log(I). Thus, the entire dataset can be characterised by horizontal and vertical logarithmic shifts of a fixed-shape template. Shape invariance can be predicted by a simple model of visual processing built from a sequence of low-pass filters, subtractive feedforward stages and gain adjustment (Rider, Henning & Stockman, 2019). It depends primarily on the numbers of visual processing stages that approach their power-law region at a given intensity and a frequency-independent gain reduction at higher light levels. Counter-intuitively, the CFF-versus-I relation depends primarily on the gain of the visual response rather than its speed-a conclusion that changes our understanding and interpretation of human flicker perception. The Ferry-Porter "law" is merely an approximation of the shape-invariant template. [ABSTRACT FROM AUTHOR]

Published

2022

17. Novel mutations in the OPN1LW and NR2R3 genes in a patient with blue cone monochromacy

Author

Shuo Sun, Lu Chen, Linni Wang, Jin Yang, Bincui Cai, Zhiqing Li, and Xiaorong Li

Subjects

0301 basic medicine, Genetics, Male, Rod Opsins, Color Vision Defects, 030105 genetics & heredity, Biology, Middle Aged, NR2E3 gene, Orphan Nuclear Receptors, Prognosis, Pedigree, 03 medical and health sciences, Ophthalmology, 0302 clinical medicine, BLUE CONE MONOCHROMACY, OPN1LW, Enhanced S-Cone Syndrome, Pediatrics, Perinatology and Child Health, 030221 ophthalmology & optometry, Humans, Female, Gene, Genetics (clinical)

Abstract

To clarify the diagnosis of a Chinese patient with novel double heterozygous in the NR2E3 and OPN1LW genes and describe the clinical features.A 47-year-old man presented with an 8-year history of decreased vision and poor night vision. Based on his clinical phenotype, we focused on 36 genes associated with these characteristics. Possible pathogenic mutation sites were screened by next-generation sequencing (NGS), which showed novel mutations in the NR2E3 and OPN1LW genes. These mutations were confirmed in the patient's sister and daughter by Sanger sequencing. To clarify the diagnosis, the clinical symptoms of the patient were observed and analyzed in combination with comprehensive ophthalmologic examinations.Genetic analysis identified the presence of novel double heterozygous of c.361GA; p.E121K in NR2E3, a gene responsible for enhanced S-cone syndrome (ESCS; OMIM #268100) and c.244AG; p.K82E in OPN1LW, a gene responsible for blue cone monochromacy (BCM; OMIM#303700). No typical clinical presentation or fundus features were found. The differential diagnosis of ESCS was excluded by electroretinography (ERG) due to the lack of characteristic abnormalities associated with ESCS. Based on the clinical manifestations and comprehensive ophthalmologic examinations, the patient was diagnosed with BCM.The novel mutations of c.244AG; p.K82E in the OPN1LW gene and c.361GA; p.E121K in the NR2E3 gene both cause BCM, but OPN1LW gene mutation dominated the retinal degeneration, resulting in the clinical features observed in this patient. These novel double heterozygous may be helpful for future genetic diagnosis and treatment for BCM.

Published

2019

18. Genotype determination of the OPN1LW/OPN1MW genes: novel disease-causing mechanisms in Japanese patients with blue cone monochromacy

Author

Tadashi Nakano, Hidehito Inagaki, Kazuki Kuniyoshi, Hiroki Kurahashi, Takahiro Yamashita, Masahito Ohji, Maki Iwasa, Hisakazu Ogita, Katsuhiro Hosono, Hisao Ueyama, Yoshihiro Hotta, Satoshi Katagiri, Hiroyuki Kondo, Takaaki Hayashi, Yoshinori Shichida, Mineo Kondo, and Shinji Ueno

Subjects

0301 basic medicine, Adult, Male, Genotype, Science, Mutant, Color Vision Defects, Biology, medicine.disease_cause, Article, 03 medical and health sciences, Exon, Japan, medicine, Humans, Promoter Regions, Genetic, Gene, Locus control region, Sequence Deletion, Genetics, Mutation, Reporter gene, Multidisciplinary, Rod Opsins, Promoter, Exons, Pedigree, 030104 developmental biology, OPN1LW, Retinal Cone Photoreceptor Cells, Medicine

Abstract

Blue cone monochromacy (BCM) is characterized by loss of function of both OPN1LW (the first) and OPN1MW (the downstream) genes on the X chromosome. The purpose of this study was to investigate the first and downstream genes in the OPN1LW/OPN1MW array in four unrelated Japanese males with BCM. In Case 1, only one gene was present. Abnormalities were found in the promoter, which had a mixed unique profile of first and downstream gene promoters and a −71A > C substitution. As the promoter was active in the reporter assay, the cause of BCM remains unclear. In Case 2, the same novel mutation, M273K, was present in exon 5 of both genes in a two-gene array. The mutant pigments showed no absorbance at any of the wavelengths tested, suggesting that the mutation causes pigment dysfunction. Case 3 had a large deletion including the locus control region and entire first gene. Case 4 also had a large deletion involving exons 2–6 of the first gene. As an intact LCR was present upstream and one apparently normal downstream gene was present, BCM in Case 4 was not ascribed solely to the deletion. The deletions in Cases 3 and 4 were considered to have been caused by non-homologous recombination.

Published

2018

19. Euarchontan Opsin Variation Brings New Focus to Primate Origins

Author

Amanda D. Melin, Nathaniel J. Dominy, George H. Perry, Maklarin B. Lakim, Robert M. Timm, Joseph D. Orkin, Gillian L. Moritz, Henry Bernard, Logan Kistler, Shoji Kawamura, and Konstans Wells

Subjects

Primates, 0301 basic medicine, genetic structures, Ultraviolet Rays, Color vision, Zoology, Evolution, Molecular, 03 medical and health sciences, Treeshrew, biology.animal, Genetics, Animals, Humans, Ptilocercus lowii, Primate, Euarchonta, Ptilocercus, Molecular Biology, Phylogeny, Discoveries, Ecology, Evolution, Behavior and Systematics, Tupaia, QL, Dendrogale, Color Vision, Opsins, biology, Rod Opsins, Opossums, Caluromys, biology.organism_classification, 030104 developmental biology, OPN1LW, sensory ecology, Central American woolly opossum

Abstract

Debate on the adaptive origins of primates has long focused on the functional ecology of the primate visual system. For example, it is hypothesized that variable expression of short- (SWS1) and middle-to-long-wavelength sensitive (M/LWS) opsins, which confer color vision, can be used to infer ancestral activity patterns and therefore selective ecological pressures. A problem with this approach is that opsin gene variation is incompletely known in the grandorder Euarchonta, that is, the orders Scandentia (treeshrews), Dermoptera (colugos), and Primates. The ancestral state of primate color vision is therefore uncertain. Here, we report on the genes (OPN1SW and OPN1LW) that encode SWS1 and M/LWS opsins in seven species of treeshrew, including the sole nocturnal scandentian Ptilocercus lowii. In addition, we examined the opsin genes of the Central American woolly opossum (Caluromys derbianus), an enduring ecological analogue in the debate on primate origins. Our results indicate: 1) retention of ultraviolet (UV) visual sensitivity in C. derbianus and a shift from UV to blue spectral sensitivities at the base of Euarchonta; 2) ancient pseudogenization of OPN1SW in the ancestors of P. lowii, but a signature of purifying selection in those of C. derbianus; and, 3) the absence of OPN1LW polymorphism among diurnal treeshrews. These findings suggest functional variation in the color vision of nocturnal mammals and a distinctive visual ecology of early primates, perhaps one that demanded greater spatial resolution under light levels that could support cone-mediated color discrimination.

Published

2016

20. The influence of L-opsin gene polymorphisms and neural ageing on spatio-chromatic contrast sensitivity in 20–71 year olds

Author

Rigmor C. Baraas, Elise W. Dees, Stuart J. Gilson, and Maureen Neitz

Subjects

Adult, Male, Aging, Opsin, medicine.medical_specialty, genetic structures, Color vision, Color space, Biology, Stimulus (physiology), Audiology, Polymorphism, Single Nucleotide, law.invention, Contrast Sensitivity, Young Adult, Optics, law, OPN1MW, medicine, Humans, Aged, Color Vision, Opsins, business.industry, Middle Aged, Sensory Systems, Ophthalmology, Achromatic lens, Ageing, OPN1LW, Female, business, Color Perception, Photic Stimulation

Abstract

Chromatic contrast sensitivity may be a more sensitive measure of an individual's visual function than achromatic contrast sensitivity. Here, the first aim was to quantify individual- and age-related variations in chromatic contrast sensitivity to a range of spatial frequencies for stimuli along two complementary directions in color space. The second aim was to examine whether polymorphisms at specific amino acid residues of the L- and M-opsin genes (OPN1LW and OPN1MW) known to affect spectral tuning of the photoreceptors could influence spatio-chromatic contrast sensitivity. Chromatic contrast sensitivity functions were measured in 50 healthy individuals (20-71 years) employing a novel pseudo-isochromatic grating stimulus. The spatio-chromatic contrast sensitivity functions were found to be low pass for all subjects, independent of age and color vision. The results revealed a senescent decline in spatio-chromatic contrast sensitivity. There were considerable between-individual differences in sensitivity within each age decade for individuals 49 years old or younger, and age did not predict sensitivity for these age decades alone. Forty-six subjects (including a color deficient male and eight female carriers) were genotyped for L- and M-opsin genes. The Ser180Ala polymorphisms on the L-opsin gene were found to influence the subject's color discrimination and their sensitivity to spatio-chromatic patterns. The results expose the significant role of neural and genetic factors in the deterioration of visual function with increasing age.

Published

2015

21. High-resolution microarray analysis unravels complex Xq28 aberrations in patients and carriers affected by X-linked blue cone monochromacy

Author

Svetlana A. Yatsenko, Alexander N. Yatsenko, Urvashi Surti, Aleksandar Rajkovic, Michelle A. Wood-Trageser, Barbara J. Jennings, Heather A. Bakos, Stephen Cercone, Alessandro Iannaccone, Marina Kedrov, Kathleen Vitullo, and Archana Kishore

Subjects

0301 basic medicine, Genetics, Microarray analysis techniques, Breakpoint, Biology, Molecular biology, Xq28, 03 medical and health sciences, 030104 developmental biology, OPN1LW, Gene cluster, OPN1MW, Genetics (clinical), X chromosome, Comparative genomic hybridization

Abstract

The human X chromosome contains ∼ 1600 genes, about 15% of which have been associated with a specific genetic condition, mainly affecting males. Blue cone monochromacy (BCM) is an X-linked condition caused by a loss-of-function of both the OPN1LW and OPN1MW opsin genes. The cone opsin gene cluster is composed of 2-9 paralogs with 99.8% sequence homology and is susceptible to deletions, duplications, and mutations. Current diagnostic tests employ polymerase chain reaction (PCR)-based technologies; however, alterations remain undetermined in 10% of patients. Furthermore, carrier testing in females is limited or unavailable. High-resolution X chromosome-targeted CGH microarray was applied to test for rearrangements in males with BCM and female carriers from three unrelated families. Pathogenic alterations were revealed in all probands, characterized by sequencing of the breakpoint junctions and quantitative real-time PCR. In two families, we identified a novel founder mutation that consisted of a complex 3-kb deletion that embraced the cis-regulatory locus control region and insertion of an additional aberrant OPN1MW gene. The application of high-resolution X-chromosome microarray in clinical diagnosis brings significant advantages in detection of small aberrations that are beyond the resolution of clinically available aCGH analysis and which can improve molecular diagnosis of the known conditions and unravel previously unrecognized X-linked diseases.

Published

2015

22. OPN1LW and OPN1MW

Author

Michel Michaelides, Thiran Jayasundera, Mark E. Pennesi, Kari Branham, Sarwar Zahid, Dana Schlegel, and John R. Heckenlively

Subjects

Physics, genetic structures, High myopia, medicine.disease, Molecular biology, Red-green dyschromatopsia, BLUE CONE MONOCHROMACY, Cone dystrophy, Cone (topology), OPN1LW, OPN1MW, medicine, sense organs, Dyschromatopsia

Abstract

OPN1LW and OPN1MW lie side by side on the X-chromosome and encode the long-wavelength (red) and middle-wavelength (green) cone opsins, respectively. Mutations in these genes cause a wide array of X-linked conditions ranging from red-green dyschromatopsia, blue cone monochromacy (BCM), cone/cone-rod dystrophy, and high myopia.

Published

2018

23. Gene-based Therapy in a Mouse Model of Blue Cone Monochromacy

Author

Wolfgang Baehr, Yuxin Zhang, Jijing Pang, Jie Li, Ping Zhu, Wei Du, Cecilia D. Gerstner, Jingfen Sun, Chen Zhao, Fan Xu, Wen-Tao Deng, William W. Hauswirth, and Sanford L. Boye

Subjects

0301 basic medicine, medicine.medical_specialty, Opsin, genetic structures, Color vision, media_common.quotation_subject, Science, Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Ophthalmology, medicine, OPN1MW, Contrast (vision), media_common, Retina, Multidisciplinary, medicine.diagnostic_test, eye diseases, Cell biology, 030104 developmental biology, medicine.anatomical_structure, OPN1LW, Knockout mouse, 030221 ophthalmology & optometry, Medicine, sense organs, Electroretinography

Abstract

Cones are responsible for daylight, central, high acuity and color vision. Three proteins found in human cones, i.e. long-wavelength (L)-, middle-wavelength (M)-, and short-wavelength sensitive (S)-opsins, are responsible for red, green and blue color recognition, respectively. Human blue cone monochromacy (BCM) is characterized by functional loss of both L- and M-cone opsins due to mutations in the OPN1LW/OPN1MW gene cluster on the X chromosome. BCM patients, who rely on their vision from only S-cones and rods, suffer severely reduced visual acuity and impaired color vision. Recent studies show that there is sufficient cone structure remaining in the central fovea of BCM patients to consider AAV-mediated gene augmentation therapy. In contrast, mouse retina has only two opsins, S-opsin and M-opsin, but no L-opsin. We generated an M-opsin knockout mouse (Opn1mw−/−) expressing only S-opsin as a model for human BCM. We show that recombinant M-opsin delivered by AAV5 vectors rescues M-cone function in Opn1mw−/− mice. We also show that AAV delivered M-opsin localizes in the dorsal cone outer segments, and co-localizes with S-opsin in the ventral retina. Our study demonstrates that cones without M-opsin remain viable and respond to gene augmentation therapy, thereby providing proof-of-concept for cone function restoration in BCM patients.

Published

2017

24. Ablation of EYS in zebrafish causes mislocalisation of outer segment proteins, F-actin disruption and cone-rod dystrophy

Author

Daji Luo, Shanshan Yu, Zhaohui Tang, Dinesh C. Soares, Zhaojing Lu, Fei Liu, Xiliang Liu, Chang Li, Meng Gao, Mugen Liu, Xuebin Hu, Yayun Qin, Tao Jiang, Shanshan Han, and An-Yuan Guo

Subjects

0301 basic medicine, Retinal degeneration, medicine.medical_specialty, Aging, Light Signal Transduction, genetic structures, Apoptosis, Article, 03 medical and health sciences, Gene Knockout Techniques, Ophthalmology, Transcription Activator-Like Effector Nucleases, Journal Article, medicine, Electroretinography, Animals, Eye Proteins, Zebrafish, Vision, Ocular, Retina, Multidisciplinary, biology, medicine.diagnostic_test, Base Sequence, Dystrophy, Zebrafish Proteins, medicine.disease, biology.organism_classification, Rod Cell Outer Segment, eye diseases, Actins, Cell biology, Transport protein, 030104 developmental biology, medicine.anatomical_structure, OPN1LW, Rhodopsin, biology.protein, sense organs, Cone-Rod Dystrophies, Gene Deletion

Abstract

Mutations in EYS are associated with autosomal recessive retinitis pigmentosa (arRP) and autosomal recessive cone-rod dystrophy (arCRD) however, the function of EYS and the molecular mechanisms of how these mutations cause retinal degeneration are still unclear. Because EYS is absent in mouse and rat, and the structure of the retina differs substantially between humans and Drosophila, we utilised zebrafish as a model organism to study the function of EYS in the retina. We constructed an EYS-knockout zebrafish-line by TALEN technology which showed visual impairment at an early age, while the histological and immunofluorescence assays indicated the presence of progressive retinal degeneration with a cone predominately affected pattern. These phenotypes recapitulate the clinical manifestations of arCRD patients. Furthermore, the EYS−/− zebrafish also showed mislocalisation of certain outer segment proteins (rhodopsin, opn1lw, opn1sw1, GNB3 and PRPH2), and disruption of actin filaments in photoreceptors. Protein mislocalisation may, therefore, disrupt the function of cones and rods in these zebrafish and cause photoreceptor death. Collectively, these results point to a novel role for EYS in maintaining the morphological structure of F-actin and in protein transport, loss of this function might be the trigger for the resultant cellular events that ultimately lead to photoreceptor death.

Published

2017

25. Comment: Novel mutations in the OPN1LW and NR2R3 genes in a patient with blue cone monochromacy

Author

Pascal Escher

Subjects

0301 basic medicine, Genetics, genetic structures, 030105 genetics & heredity, Biology, eye diseases, 3. Good health, 03 medical and health sciences, Ophthalmology, 0302 clinical medicine, BLUE CONE MONOCHROMACY, Color Vision Defects, OPN1LW, Pediatrics, Perinatology and Child Health, Mutation (genetic algorithm), 030221 ophthalmology & optometry, sense organs, Gene, Genetics (clinical)

Abstract

I was puzzled by the conclusions of the article by Cai et al. entitled “Novel mutations in the OPN1LW and NR2E3 genes in a patient with blue cone monochromacy” (1). The authors state there that “th...

Published

2019

26. Progress in treating inherited retinal diseases: Early subretinal gene therapy clinical trials and candidates for future initiatives.

Author

Garafalo, Alexandra V., Cideciyan, Artur V., Héon, Elise, Sheplock, Rebecca, Pearson, Alexander, WeiYang Yu, Caberry, Sumaroka, Alexander, Aguirre, Gustavo D., and Jacobson, Samuel G.

Subjects

*RETINAL diseases, *GENE therapy, *GENETIC disorders, *GENE delivery techniques, *CLINICAL trials

Abstract

Due to improved phenotyping and genetic characterization, the field of 'incurable' and 'blinding' inherited retinal diseases (IRDs) has moved substantially forward. Decades of ascertainment of IRD patient data from Philadelphia and Toronto centers illustrate the progress from Mendelian genetic types to molecular diagnoses. Molecular genetics have been used not only to clarify diagnoses and to direct counseling but also to enable the first clinical trials of gene-based treatment in these diseases. An overview of the recent reports of gene augmentation clinical trials by subretinal injections is used to reflect on the reasons why there has been limited success in this early venture into therapy. These first-in human experiences have taught that there is a need for advancing the techniques of delivery of the gene products - not only for refining further subretinal trials, but also for evaluating intravitreal delivery. Candidate IRDs for intravitreal gene delivery are then suggested to illustrate some of the disorders that may be amenable to improvement of remaining central vision with the least photoreceptor trauma. A more detailed understanding of the human IRDs to be considered for therapy and the calculated potential for efficacy should be among the routine prerequisites for initiating a clinical trial. [ABSTRACT FROM AUTHOR]

Published

2020

27. Human Cone Visual Pigment Deletions Spare Sufficient Photoreceptors to Warrant Gene Therapy

Author

Robert A. Sisk, Alison J. Hardcastle, Samuel G. Jacobson, Robert B. Hufnagel, Michel Michaelides, Anthony T. Moore, Xunda Luo, Bernd Wissinger, Sharon B. Schwartz, Zubair M. Ahmed, Megan E. Land, Jessica C. Gardner, Joseph Carroll, Alfredo Dubra, Alexander Sumaroka, Susanne Kohl, and Artur V. Cideciyan

Subjects

Adult, Opsin, Adolescent, genetic structures, Medical Biotechnology, Clinical Sciences, Color Vision Defects, Biology, Eye, medicine.disease_cause, Monochromacy, Mice, Rare Diseases, Genetics, medicine, OPN1MW, Animals, Humans, Preschool, Child, Eye Disease and Disorders of Vision, Molecular Biology, Research Articles, Retina, Mutation, Neurosciences, Rod Opsins, Gene Therapy, Genetic Therapy, Middle Aged, medicine.disease, eye diseases, Cell biology, Orphan Drug, medicine.anatomical_structure, Regulatory sequence, Rhodopsin, OPN1LW, Child, Preschool, Retinal Cone Photoreceptor Cells, biology.protein, Molecular Medicine, Female, sense organs, Gene Deletion, Biotechnology

Abstract

Human X-linked blue-cone monochromacy (BCM), a disabling congenital visual disorder of cone photoreceptors, is a candidate disease for gene augmentation therapy. BCM is caused by either mutations in the red (OPN1LW) and green (OPN1MW) cone photoreceptor opsin gene array or large deletions encompassing portions of the gene array and upstream regulatory sequences that would predict a lack of red or green opsin expression. The fate of opsin-deficient cone cells is unknown. We know that rod opsin null mutant mice show rapid postnatal death of rod photoreceptors. Using in vivo histology with high-resolution retinal imaging, we studied a cohort of 20 BCM patients (age range 5-58) with large deletions in the red/green opsin gene array. Already in the first years of life, retinal structure was not normal: there was partial loss of photoreceptors across the central retina. Remaining cone cells had detectable outer segments that were abnormally shortened. Adaptive optics imaging confirmed the existence of inner segments at a spatial density greater than that expected for the residual blue cones. The evidence indicates that human cones in patients with deletions in the red/green opsin gene array can survive in reduced numbers with limited outer segment material, suggesting potential value of gene therapy for BCM.

Published

2013

28. Myopia and Late-Onset Progressive Cone Dystrophy Associate to LVAVA/MVAVA Exon 3 Interchange Haplotypes of Opsin Genes on Chromosome X

Author

Viktória Szabó, Attila Vajas, Istvan Balogh, Adrienne Csutak, Bence Lajos Kolozsvári, Miklós D. Resch, Lili Takács, Gergely Losonczy, Mariann Fodor, Orsolya Orosz, András Berta, Katalin Sényi, Istvan Rajta, and Balázs Lesch

Subjects

0301 basic medicine, Adult, Male, genetic structures, Adolescent, Genotype, Color vision, Color Vision Defects, Biology, Klinikai orvostudományok, Polymerase Chain Reaction, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Cone dystrophy, Retinal Rod Photoreceptor Cells, OPN1MW, medicine, Electroretinography, Myopia, Humans, Child, X chromosome, Genetic Association Studies, Genetics, Chromosomes, Human, X, Haplotype, Rod Opsins, Dystrophy, Genetic Diseases, X-Linked, DNA, Orvostudományok, Middle Aged, medicine.disease, eye diseases, Pedigree, 030104 developmental biology, Phenotype, Haplotypes, OPN1LW, 030221 ophthalmology & optometry, Disease Progression, Female, sense organs

Abstract

Purpose Rare interchange haplotypes in exon 3 of the OPN1LW and OPN1MW opsin genes cause X-linked myopia, color vision defect, and cone dysfunction. The severity of the disease varies on a broad scale from nonsyndromic high myopia to blue cone monochromatism. Here, we describe a new genotype-phenotype correlation attributed to rare exon 3 interchange haplotypes simultaneously present in the long- and middle-wavelength sensitive opsin genes (L- and M-opsin genes). Methods A multigenerational family with X-linked high myopia and cone dystrophy was investigated. Results Affected male patients had infantile onset myopia with normal visual acuity and color vision until their forties. Visual acuity decreased thereafter, along with the development of severe protan and deutan color vision defects. A mild decrease in electroretinography response of cone photoreceptors was detected in childhood, which further deteriorated in middle-aged patients. Rods were also affected, however, to a lesser extent than cones. Clinical exome sequencing identified the LVAVA and MVAVA toxic haplotypes in the OPN1LW and OPN1MW opsin genes, respectively. Conclusion Here, we show that LVAVA haplotype of the OPN1LW gene and MVAVA haplotype of the OPN1MW gene cause apparently nonsyndromic high myopia in young patients but lead to progressive cone-rod dystrophy with deuteranopia and protanopia in middle-aged patients corresponding to a previously unknown disease course. To the best of our knowledge, this is the first report on the joint effect of these toxic haplotypes in the two opsin genes on chromosome X.

Published

2017

29. Novel OPN1LW/OPN1MW deletion mutations in 2 Japanese families with blue cone monochromacy

Author

Katsuhiro Hosono, Yoshihiro Hotta, Shu Kachi, Kimiko Suto, Makoto Nakamura, Chunxia Wang, Yozo Miyake, Hiroko Terasaki, and Shinsei Minoshima

Subjects

0301 basic medicine, Genetics, Breakpoint, Biology, Biochemistry, Molecular biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, BLUE CONE MONOCHROMACY, OPN1LW, Deletion mutation, Data Report, 030221 ophthalmology & optometry, OPN1MW, Molecular Biology, Gene, Locus control region

Abstract

Blue cone monochromacy (BCM) is caused by the lack of expression of the normal proteins encoded by the OPN1LW and OPN1MW genes, resulting in the absence of red and green cone sensitivities. We analyzed two cases of BCM in two different families and identified deletion mutations in the locus control region upstream of the two genes. Deletion breakpoints were determined to an accuracy of one base for both cases.

Published

2016

30. Cone opsins, colour blindness and cone dystrophy: Genotype-phenotype correlations

Author

Alison J. Hardcastle, Michel Michaelides, and Jessica C. Gardner

Subjects

0301 basic medicine, medicine.medical_specialty, genetic structures, Genotype, Color Vision Defects, medicine.disease_cause, Monochromacy, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Cone dystrophy, Molecular genetics, Ophthalmology, medicine, OPN1MW, Humans, Molecular Biology, Genetic Association Studies, Genetics, Mutation, business.industry, Rod Opsins, Retinal, Genetic Diseases, X-Linked, General Medicine, medicine.disease, Cone Opsins, eye diseases, Xq28, 030104 developmental biology, Phenotype, chemistry, OPN1LW, 030221 ophthalmology & optometry, Retinal Cone Photoreceptor Cells, sense organs, business, Cone-Rod Dystrophies

Abstract

X-linked cone photoreceptor disorders caused by mutations in the OPN1LW (L) and OPN1MW (M) cone opsin genes on chromosome Xq28 include a range of conditions from mild stable red-green colour vision deficiencies to severe cone dystrophies causing progressive loss of vision and blindness. Advances in molecular genotyping and functional analyses of causative variants, combined with deep retinal phenotyping, are unravelling genetic mechanisms underlying the variability of cone opsin disorders.

Published

2016

31. Unique haplotype in exon 3 of cone opsin mRNA affects splicing of its precursor, leading to congenital color vision defect

Author

Sanae Muraki-Oda, Hisao Ueyama, Shoko Tanabe, Shinichi Yamade, Hisakazu Ogita, Takahiro Yamashita, and Yoshinori Shichida

Subjects

Male, Molecular Sequence Data, Mutation, Missense, Biophysics, Color Vision Defects, Biology, Biochemistry, Exon, Asian People, Japan, Humans, Amino Acid Sequence, RNA, Messenger, Northern blot, Molecular Biology, Gene, Genetics, Expression vector, Rod Opsins, Intron, Exons, Cell Biology, Cone Opsins, Molecular biology, Alternative Splicing, HEK293 Cells, Haplotypes, OPN1LW, RNA splicing, Minigene

Abstract

We have analyzed L/M visual pigment gene arrays in 119 Japanese men with protanopia color vision defect and found that five had a normal gene order of L-M. Among the five men, two (identified as A376 and A642) had apparently normal L genes. To clarify their L gene defect, the whole L or M gene from A376 and control subjects was cloned in an expression vector. Total RNA extracted from the transfected HEK293 cells was analyzed by Northern blot and reverse transcription-polymerase chain reaction. The product from the cloned L gene of A376 was smaller than the normal control due to the absence of exon 3. To investigate such exon-skipping at splicing, minigenes of exon 3 accompanying introns 2 and 3 were prepared from A376, A642, and control subjects. The minigenes of A376 (L) and A642 (L) showed the product lacking exon 3 only, while the minigene of normal control N44 (L) showed the product retaining exon 3 only. Exchanging of introns 2 and 3 between the A376 (L) and N44 (L) minigenes showed that the skipping of exon 3 was caused by the exon itself. Seven differences in exon 3 between A376 (L) and N44 (L) were all within already-known polymorphisms as follows: G(151-3), C(153-1), G(155-3), A(171-1), T(171-3), G(178-1) and G(180-1) in A376 (L) and A642 (L), and A(151-3), A(153-1), C(155-3), G(171-1), G(171-3), A(178-1) and T(180-1) in N44 (L). An in vitro mutagenesis experiment with these nucleotides in the minigenes showed that exon 3 was completely skipped at splicing only in the haplotype observed in A376 (L) and A642 (L). These results suggest that complete skipping of exon 3 at splicing, due to the unique haplotype of the exon, causes loss of expression of L-opsin in these men.

Published

2012

32. The genetics of normal and defective color vision

Author

Maureen Neitz and Jay Neitz

Subjects

Opsin, genetic structures, Evolution, Computer science, Color vision, Color Vision Defects, Opsin genes, medicine.disease_cause, Retinal Cone Photoreceptor Cells, Article, Retinal Rod Photoreceptor Cells, Colorblindness, Comparative color vision, OPN1MW, medicine, Animals, Humans, Cone mosaic, Genetics, Mutation, Cone photopigments, Cone photoreceptor, eye diseases, Sensory Systems, Ophthalmology, OPN1LW, Circuitry, sense organs, Retinal Pigments, Color Perception

Abstract

The contributions of genetics research to the science of normal and defective color vision over the previous few decades are reviewed emphasizing the developments in the 25years since the last anniversary issue of Vision Research. Understanding of the biology underlying color vision has been vaulted forward through the application of the tools of molecular genetics. For all their complexity, the biological processes responsible for color vision are more accessible than for many other neural systems. This is partly because of the wealth of genetic variations that affect color perception, both within and across species, and because components of the color vision system lend themselves to genetic manipulation. Mutations and rearrangements in the genes encoding the long, middle, and short wavelength sensitive cone pigments are responsible for color vision deficiencies and mutations have been identified that affect the number of cone types, the absorption spectra of the pigments, the functionality and viability of the cones, and the topography of the cone mosaic. The addition of an opsin gene, as occurred in the evolution of primate color vision, and has been done in experimental animals can produce expanded color vision capacities and this has provided insight into the underlying neural circuitry.

Published

2011

33. Opsin 3-G αs Promotes Airway Smooth Muscle Relaxation Modulated by G Protein Receptor Kinase 2.

Author

Wu AD, Dan W, Zhang Y, Vemaraju S, Upton BA, Lang RA, Buhr ED, Berkowitz DE, Gallos G, Emala CW, and Yim PD

Subjects

Animals, Cells, Cultured, Cyclic AMP metabolism, Cyclic AMP-Dependent Protein Kinases metabolism, Humans, Male, Mice, Mice, Inbred C57BL, Opsins metabolism, Signal Transduction physiology, G-Protein-Coupled Receptor Kinase 2 metabolism, Muscle Relaxation physiology, Muscle, Smooth metabolism, Myocytes, Smooth Muscle metabolism, Rod Opsins metabolism, Trachea metabolism

Abstract

Recently, we characterized blue light-mediated relaxation (photorelaxation) of airway smooth muscle (ASM) and implicated the involvement of opsin 3 (OPN3), an atypical opsin. In the present study, we characterized the cellular signaling mechanisms of photorelaxation. We confirmed the functional role of OPN3 in blue light photorelaxation using trachea from OPN3 null mice (maximal relaxation 52 ± 13% compared with wild-type mice 90 ± 4.3%, P  < 0.05). We then demonstrated colocalization of OPN3 and G α s using co-IP and proximity ligation assays in primary human ASM cells, which was further supported by an increase in cAMP in mouse trachea treated with blue light compared with dark controls (23 ± 3.6 vs. 14 ± 2.6 pmol cAMP/ring, P  < 0.05). Downstream PKA (protein kinase A) involvement was shown by inhibiting photorelaxation using Rp-cAMPS ( P  < 0.0001). Moreover, we observed converging mechanisms of desensitization by chronic β 2 -agonist exposure in mouse trachea and correlated this finding with colocalization of OPN3 and GRK2 (G protein receptor kinase) in primary human ASM cells. Finally, an overexpression model of OPN1LW (a red light photoreceptor in the same opsin family) in human ASM cells showed an increase in intracellular cAMP levels following red light exposure compared with nontransfected cells (48 ± 13 vs. 13 ± 2.1 pmol cAMP/mg protein, P  < 0.01), suggesting a conserved photorelaxation mechanism for wavelengths of light that are more tissue penetrant. Together, these results demonstrate that blue light photorelaxation in ASM is mediated by the OPN3 receptor interacting with G α s , which increases cAMP levels, activating PKA and modulated by GRK2.

Published

2021

34. Unique Variants in OPN1LW Cause Both Syndromic and Nonsyndromic X-Linked High Myopia Mapped to MYP1

Author

Shiqiang Li, Jun Wang, Ye Yin, Hui Jiang, Qingjiong Zhang, Xueshan Xiao, Xiaoyun Jia, Liping Guan, Bei Gao, Xiangming Guo, Jianhua Yang, Jianguo Zhang, and Jiali Li

Subjects

Proband, Male, genetic structures, Genetic Linkage, Locus (genetics), Biology, Frameshift mutation, symbols.namesake, Asian People, Myopia, Humans, Frameshift Mutation, Gene, X-linked recessive inheritance, Genetics, Sanger sequencing, Haplotype, Rod Opsins, Chromosome Mapping, Genetic Diseases, X-Linked, Sequence Analysis, DNA, eye diseases, Pedigree, Haplotypes, OPN1LW, Myopia, Degenerative, symbols, Female, Lod Score, Microsatellite Repeats

Abstract

PURPOSE MYP1 is a locus for X-linked syndromic and nonsyndromic high myopia. Recently, unique haplotypes in OPN1LW were found to be responsible for X-linked syndromic high myopia mapped to MYP1. The current study is to test if such variants in OPN1LW are also responsible for X-linked nonsyndromic high myopia mapped to MYP1. METHODS The proband of the family previously mapped to MYP1 was initially analyzed using whole-exome sequencing and whole-genome sequencing. Additional probands with early-onset high myopia were analyzed using whole-exome sequencing. Variants in OPN1LW were selected and confirmed by Sanger sequencing. Long-range and second PCR were used to determine the haplotype and the first gene of the red-green gene array. Candidate variants were further validated in family members and controls. RESULTS The unique LVAVA haplotype in OPN1LW was detected in the family with X-linked nonsyndromic high myopia mapped to MYP1. In addition, this haplotype and a novel frameshift mutation (c.617_620dup, p.Phe208Argfs*51) in OPN1LW were detected in two other families with X-linked high myopia. The unique haplotype cosegregated with high myopia in the two families, with a maximum LOD score of 3.34 and 2.31 at θ = 0. OPN1LW with the variants in these families was the first gene in the red-green gene array and was not present in 247 male controls. Reevaluation of the clinical data in both families with the unique haplotype suggested nonsyndromic high myopia. CONCLUSIONS Our study confirms the findings that unique variants in OPN1LW are responsible for both syndromic and nonsyndromic X-linked high myopia mapped to MYP1.

Published

2015

35. Signatures of Selection and Gene Conversion Associated with Human Color Vision Variation

Author

Sarah A. Tishkoff and Brian C. Verrelli

Subjects

Male, Opsin, Pan troglodytes, genetic structures, Color vision, Statistics as Topic, Population, Black People, Biology, Polymerase Chain Reaction, Polymorphism, Single Nucleotide, Protein Structure, Secondary, 03 medical and health sciences, 0302 clinical medicine, Genetic variation, Genetics, Animals, Humans, Genetics(clinical), Photopigment, Gene conversion, education, Genetics (clinical), 030304 developmental biology, 0303 health sciences, education.field_of_study, Rod Opsins, Trichromacy, Genetic Variation, Articles, Exons, Biological Evolution, Phenotype, Databases as Topic, Haplotypes, OPN1LW, Africa, Color Perception, 030217 neurology & neurosurgery

Abstract

Trichromatic color vision in humans results from the combination of red, green, and blue photopigment opsins. Although color vision genes have been the targets of active molecular and psychophysical research on color vision abnormalities, little is known about patterns of normal genetic variation in these genes among global human populations. The current study presents nucleotide sequence analyses and tests of neutrality for a 5.5-kb region of the X-linked long-wave "red" opsin gene (OPN1LW) in 236 individuals from ethnically diverse human populations. Our analysis of the recombination landscape across OPN1LW reveals an unusual haplotype structure associated with amino acid replacement variation in exon 3 that is consistent with gene conversion. Compared with the absence of OPN1LW amino acid replacement fixation since divergence from chimpanzee, the human population exhibits a significant excess of high-frequency OPN1LW replacements. Our results suggest that subtle changes in L-cone opsin wavelength absorption may have been adaptive during human evolution.

Published

2004

36. Spectrum of color gene deletions and phenotype in patients with blue cone monochromacy

Author

Yumiko Toda, Paul A. Sieving, Eve L. Bingham, Jennifer A. Kemp, Janet J. Szczesny, Laura E. Kakuk, Joost Felius, and Radha Ayyagari

Subjects

Adult, Male, Heterozygote, X Chromosome, genetic structures, Genetic Linkage, Color vision, DNA Mutational Analysis, Biology, medicine.disease_cause, Polymerase Chain Reaction, Contig Mapping, Exon, Retinal Diseases, Genetic linkage, Genotype, Genetics, medicine, Humans, Fluorescein Angiography, Gene, Vision, Ocular, Genetics (clinical), Aged, Mutation, Models, Genetic, Exons, Middle Aged, Ophthalmoscopy, Blotting, Southern, Phenotype, OPN1LW, Child, Preschool, Retinal Cone Photoreceptor Cells, Female, Gene Deletion, Photopic vision

Abstract

Blue cone monochromacy (BCM) is an X-linked ocular disease characterized by poor visual acuity, nystagmus, and photodysphoria in males with severely reduced color discrimination. Deletions, rearrangements and point mutations in the red and green pigment genes have been implicated in causing BCM. We assessed the spectrum of genetic alterations in ten families with BCM by Southern blot, polymerase chain reaction, and sequencing analysis, and the phenotype was characterized by ophthalmoscopy, fluorescein angiography, and a battery of tests to assess color vision in addition to routine ophthalmological examination. All families showed clinical features associated with BCM. Acuities were reduced in all affected males, and photopic b-wave was reduced by more than 90% in seven families. In three families, however, the photopic b-wave response showed uncharacteristic relative preservation of 30-80% (of the clinical low-normal value). The color vision was unusually preserved in two affected males, but this was not correlated with photopic electroretinography retention. Progressive macular atrophy was observed in affected members of two BCM families while the rest of the families presented with normal fundus. In nine families deletions were identified in the gene encoding the red-sensitive photopigment and/or in the region up to 17.8 kb upstream of the red gene which contains the locus control region and other regulatory sequences. In the same nine families the red pigment gene showed a range of deletions from the loss of a single exon to loss of the complete red gene. In one family no mutation was found in the exons of the red gene or the locus control region but showed loss of the complete green gene. No association was observed between the phenotypes and genotypes in these families.

Published

2000

37. ESTABLISHING AND MANIPULATING THE DIMERIC INTERFACE OF VISUAL/NON-VISUAL OPSINS

Author

Comar, William D., Ph.D.

Subjects

Biochemistry, Physical Chemistry, Molecular Biology, G protein-coupled receptor, GPCR, Opsin, Rhodopsin, Cone Opsin, Melanopsin, Pulsed-Interleaved Excitation Fluorescence Cross-Correlation, Fluorescence, Cross Correlation, PIE-FCCS, Dimerization, OPN1LW, OPN1MW, OPN1SW, Cos-7, TRPC3-HEK293

Abstract

G protein-coupled receptors (GPCRs) make up the largest family of cell surface protein receptors and are involved in a number of diverse biological processes. The association of GPCRs, whether they be monomeric, dimeric, or oligomeric, is hypothesized to alter their signaling. Attaining crystallographic evidence of the dimeric or oligomeric associations of Class A GPCRs, specifically (non)visual opsins, remains a difficulty, as does establishing the stability of these associations. The purpose of this research was to quantify the association of (non)visual opsins, in situ, in the plasma membrane of live cells. We used a time-resolved fluorescence approach to accomplish this purpose. Pulsed-interleaved excitation fluorescence cross-correlation spectroscopy (PIE-FCCS) offered a way in which the dynamic interactions of (non)visual opsins could be quantified.Throughout this dissertation, three projects will be presented. The first project focused on the dimeric association of rhodopsin, the light sensitive protein involved in scotopic vision. By transfecting low concentrations of rhodopsin into mammalian cells, we found a modest affinity for dimerization. The second project focused on the proteins involved in trichromatic photopic vision, cone opsins. Two of the three human cone opsins, OPN1LW (red) and OPN1MW (green) share a 95% sequence homology. Despite having such a homology, red and green cone opsin showed different affinities for dimerization. Red cone opsin was observed to have the highest affinity for dimeric association among the GPCRs studied. Green cone opsin was shown to primarily exist as a monomer. Mutagenesis was performed on both red and green cone opsin in an attempt to decrease red cone opsin dimerization affinity and increase green cone opsin dimerization affinity. The third project focused on melanopsin, a non-visual human opsin. Melanopsin is expressed in the ganglion cell layer (GCL) of the retina and plays a role in both circadian rhythm and the pupillary light response. The experiments in Chapter 5 demonstrate that melanopsin has a low dimerization affinity. The affinity is higher than our monomeric controls, but lower than that of both rhodopsin and red cone opsin. Establishing the native association of these visual and non-visual opsins in the retina is a key step in determining how the spatial organization of these proteins regulates their biological function. Experiments in chapters 3, 4, and 5 begin to connect dimerization to function, but more work is needed to quantify these relationships. This work also creates a paradigm in which GPCR dimerization can be quantified and contextualized, which is critical for developing new pharmaceutical treatments for this important class of proteins.

Published

2018

38. Gene Conversion between Red and Defective Green Opsin Gene in Blue Cone Monochromacy

Author

Kestelijn P, De Boulle K, Reyniers E, Devries K, P. J. Willems, Meire F, and Van Thienen Mn

Subjects

Male, Opsin, X Chromosome, Genetic Linkage, Molecular Sequence Data, Gene Conversion, Color Vision Defects, Gene mutation, Biology, medicine.disease_cause, Polymerase Chain Reaction, Retinal Cone Photoreceptor Cells, Exon, Genetics, medicine, Humans, Point Mutation, Gene conversion, DNA Primers, Mutation, Base Sequence, Rod Opsins, Chromosome Mapping, Gene rearrangement, Pedigree, OPN1LW, Female, sense organs, Color Perception

Abstract

Blue cone monochromacy is an X-linked condition in which the function of both the red pigment gene (RCP) and the green pigment gene (GCP) is impaired. Blue cone monochromacy can be due to a red/green gene array rearrangement existing of a single red/green hybrid gene and an inactivating C203R point mutation in GCP. We describe here a family with blue cone monochromacy due to the presence of the C203R mutation in both RCP and GCP. The flanking sequences of the C203R mutation in exon 4 of RCP were characteristic for GCP, indicating that this mutation was transferred from GCP into RCP by gene conversion.

Published

1995

39. The effect of cone opsin mutations on retinal structure and the integrity of the photoreceptor mosaic

Author

David R. Williams, Anthony T. Moore, Michel Michaelides, Liliana Mizrahi-Meissonnier, David M. Hunt, Eyal Banin, Maureen Neitz, Alison J. Hardcastle, Jessica C. Gardner, Gerald A. Fishman, Mohamed A. Genead, Jay Neitz, Thomas B. Connor, Rick N. Nordgren, Robert F. Cooper, Adam M. Dubis, Joseph Carroll, Kimberly E. Stepien, Dror Sharon, and Alfredo Dubra

Subjects

Retinal degeneration, Adult, Male, Opsin, medicine.medical_specialty, Achromatopsia, Visual acuity, genetic structures, Adolescent, DNA Mutational Analysis, Visual Acuity, Color Vision Defects, Biology, chemistry.chemical_compound, Young Adult, Ophthalmology, OPN1MW, medicine, Humans, Retina, Retinal Degeneration, Rod Opsins, Retinal, Anatomy, Articles, Middle Aged, medicine.disease, Cone Opsins, Ophthalmoscopy, medicine.anatomical_structure, Phenotype, chemistry, OPN1LW, Mutation, Female, sense organs, medicine.symptom, Tomography, Optical Coherence, Photoreceptor Cells, Vertebrate

Abstract

To evaluate retinal structure and photoreceptor mosaic integrity in subjects with OPN1LW and OPN1MW mutations.Eleven subjects were recruited, eight of whom have been previously described. Cone and rod density was measured using images of the photoreceptor mosaic obtained from an adaptive optics scanning light ophthalmoscope (AOSLO). Total retinal thickness, inner retinal thickness, and outer nuclear layer plus Henle fiber layer (ONL+HFL) thickness were measured using cross-sectional spectral-domain optical coherence tomography (SD-OCT) images. Molecular genetic analyses were performed to characterize the OPN1LW/OPN1MW gene array.While disruptions in retinal lamination and cone mosaic structure were observed in all subjects, genotype-specific differences were also observed. For example, subjects with "L/M interchange" mutations resulting from intermixing of ancestral OPN1LW and OPN1MW genes had significant residual cone structure in the parafovea (∼25% of normal), despite widespread retinal disruption that included a large foveal lesion and thinning of the parafoveal inner retina. These subjects also reported a later-onset, progressive loss of visual function. In contrast, subjects with the C203R missense mutation presented with congenital blue cone monochromacy, with retinal lamination defects being restricted to the ONL+HFL and the degree of residual cone structure (8% of normal) being consistent with that expected for the S-cone submosaic.The photoreceptor phenotype associated with OPN1LW and OPN1MW mutations is highly variable. These findings have implications for the potential restoration of visual function in subjects with opsin mutations. Our study highlights the importance of high-resolution phenotyping to characterize cellular structure in inherited retinal disease; such information will be critical for selecting patients most likely to respond to therapeutic intervention and for establishing a baseline for evaluating treatment efficacy.

Published

2012

40. Blue cone monochromatism in a female due to skewed X-inactivation

Author

Morten Duno, Anja Lisbeth Frederiksen, and Lotte G Welinder

Subjects

Male, Pathology, medicine.medical_specialty, genetic structures, Vision Disorders, Visual Acuity, Color Vision Defects, Biology, Polymerase Chain Reaction, X-inactivation, Cone dystrophy, X Chromosome Inactivation, medicine, Electroretinography, Humans, Point Mutation, Color perception test, Skewed X-inactivation, Genetics (clinical), Genetics, Color Perception Tests, medicine.diagnostic_test, Point mutation, Rod Opsins, medicine.disease, Pedigree, Ophthalmology, OPN1LW, Child, Preschool, Pediatrics, Perinatology and Child Health, Female, sense organs, Tomography, Optical Coherence

Abstract

Blue cone monochromatism (BCM) is a rare cone dystrophy with recessive X-linked inheritance and therefore diagnosed in males whereas females are clinically unaffected. We present a female with clinically manifested BCM. The diagnosis was genetically verified with the identification of one single red-green OPN1LW/MW hybrid gene harboring a point mutation c.607C>G, p.Cys203Arg that associates with BCM and in addition a completely biased X-inactivation in DNA isolated from full blood and buccal mucosa. The present case illustrates that females may develop symptoms of recessive X-linked eye diseases in rare cases.

Published

2012

41. Cell-specific DNA methylation patterns of retina-specific genes

Author

Verity F. Oliver, Laszlo Hackler, Jiang Qian, Miriam A. Khan, Shannath L. Merbs, Donald J. Zack, and Jun Wan

Subjects

genetic structures, Bisulfite sequencing, Gene Expression, lcsh:Medicine, Biochemistry, Mice, 0302 clinical medicine, Retinal Rod Photoreceptor Cells, Nucleic Acids, Molecular Cell Biology, OPN1MW, Cloning, Molecular, lcsh:Science, Regulation of gene expression, 0303 health sciences, Multidisciplinary, Physics, Organ Specificity, OPN1LW, DNA methylation, Retinal Cone Photoreceptor Cells, Medicine, Epigenetics, Research Article, Retinal Neurons, Retinal binding, Biophysics, Biology, Retina, Cell Line, Molecular Genetics, 03 medical and health sciences, Epigenetics of physical exercise, Genetics, Animals, Humans, Sulfites, 030304 developmental biology, lcsh:R, DNA, Sequence Analysis, DNA, DNA Methylation, Molecular biology, eye diseases, Ophthalmology, CpG Islands, lcsh:Q, sense organs, 030217 neurology & neurosurgery

Abstract

Many studies have demonstrated that epigenetic mechanisms are important in the regulation of gene expression during embryogenesis, gametogenesis, and other forms of tissue-specific gene regulation. We sought to explore the possible role of epigenetics, specifically DNA methylation, in the establishment and maintenance of cell type-restricted gene expression in the retina. To assess the relationship between DNA methylation status and expression level of retinal genes, bisulfite sequence analysis of the 1000 bp region around the transcription start sites (TSS) of representative rod and cone photoreceptor-specific genes and gene expression analysis were performed in the WERI and Y79 human retinoblastoma cell lines. Next, the homologous genes in mouse were bisulfite sequenced in the retina and in non-expressing tissues. Finally, bisulfite sequencing was performed on isolated photoreceptor and non-photoreceptor retinal cells isolated by laser capture microdissection. Differential methylation of rhodopsin (RHO), retinal binding protein 3 (RBP3, IRBP) cone opsin, short-wave-sensitive (OPN1SW), cone opsin, middle-wave-sensitive (OPN1MW), and cone opsin, long-wave-sensitive (OPN1LW) was found in the retinoblastoma cell lines that inversely correlated with gene expression levels. Similarly, we found tissue-specific hypomethylation of the promoter region of Rho and Rbp3 in mouse retina as compared to non-expressing tissues, and also observed hypomethylation of retinal-expressed microRNAs. The Rho and Rbp3 promoter regions were unmethylated in expressing photoreceptor cells and methylated in non-expressing, non-photoreceptor cells from the inner nuclear layer. A third regional hypomethylation pattern of photoreceptor-specific genes was seen in a subpopulation of non-expressing photoreceptors (Rho in cones from the Nrl -/- mouse and Opn1sw in rods). These results demonstrate that a number of photoreceptor-specific genes have cell-specific differential DNA methylation that correlates inversely with their expression level. Furthermore, these cell-specific patterns suggest that DNA methylation may play an important role in modulating photoreceptor gene expression in the developing mammalian retina.

Published

2012

42. A Novel Missense Mutation in Both OPN1LW and OPN1MW Cone Opsin Genes Causes X-Linked Cone Dystrophy (XLCOD5)

Author

Michael E. Cheetham, Michel Michaelides, Caterina Ripamonti, Neil D. Ebenezer, Alison J. Hardcastle, Jessica C. Gardner, Olufunmilola A. Ogun, Tom R. Webb, Naheed Kanuga, Anthony T. Moore, Eamonn R. Maher, Graham E. Holder, Anthony G. Robson, Genevieve A. Wright, Andrew Stockman, and Sophie Devery

Subjects

Retinal degeneration, Genetics, Opsin, genetic structures, Biology, medicine.disease, Retinal Cone Photoreceptor Cells, eye diseases, Exon, Cone dystrophy, OPN1LW, OPN1MW, medicine, Missense mutation, sense organs

Abstract

X-linked cone and cone-rod dystrophies (XLCOD and XLCORD) are an inherited group of retinal disorders primarily involving cone photoreceptors. The most common cause is mutation of RPGR. In a British family with XLCOD, we mapped the disorder to Xq26.1-qter, excluding RPGR and other known retinal degeneration genes. The cone opsin gene array on Xq28 was a positional candidate locus. A novel missense mutation (c.529T > C; p.W177R) was identified in exon 3 of both the long wavelength-sensitive (OPN1LW; LW, red) and medium wavelength-sensitive (OPN1MW; MW, green) cone opsin genes, which segregated with disease. Exon 3 sequences of both genes were identical, derived from the OPN1MW gene by partial gene conversion. The amino acid W177 is conserved in all opsins across species. We have shown that W177R in MW opsin results in protein misfolding and retention in the endoplasmic reticulum (ER). Mutations in the OPN1LW /OPN1MW cone opsin gene array can therefore cause a spectrum of phenotypes, from colour blindness to progressive cone dystrophy (XLCOD5).

Published

2011

43. X-linked cone dystrophy caused by mutation of the red and green cone opsins

Author

Anthony T. Moore, Graham E. Holder, Anthony G. Robson, Alison J. Hardcastle, Caterina Ripamonti, Andrew Stockman, Sophie Devery, Olufunmilola A. Ogun, Michael E. Cheetham, Michel Michaelides, Genevieve A. Wright, Eamonn R. Maher, Tom R. Webb, Neil D. Ebenezer, Naheed Kanuga, and Jessica C. Gardner

Subjects

Adult, Male, Opsin, genetic structures, Adolescent, Genetic Linkage, Molecular Sequence Data, Mutation, Missense, Biology, Retinal Cone Photoreceptor Cells, Protein Structure, Secondary, Article, 03 medical and health sciences, Exon, 0302 clinical medicine, Cone dystrophy, Retinal Diseases, Retinitis pigmentosa, Genetics, medicine, OPN1MW, Missense mutation, Humans, Genetics(clinical), Amino Acid Sequence, Genetics (clinical), Genetic Association Studies, 030304 developmental biology, Aged, Aged, 80 and over, 0303 health sciences, Chromosomes, Human, X, Genetic Diseases, X-Linked, Middle Aged, medicine.disease, Cone Opsins, eye diseases, Pedigree, Haplotypes, OPN1LW, Genetic Loci, 030221 ophthalmology & optometry, Female, sense organs, Lod Score

Abstract

X-linked cone and cone-rod dystrophies (XLCOD and XLCORD) are a heterogeneous group of progressive disorders that solely or primarily affect cone photoreceptors. Mutations in exon ORF15 of the RPGR gene are the most common underlying cause. In a previous study, we excluded RPGR exon ORF15 in some families with XLCOD. Here, we report genetic mapping of XLCOD to Xq26.1-qter. A significant LOD score was detected with marker DXS8045 (Z(max) = 2.41 [theta = 0.0]). The disease locus encompasses the cone opsin gene array on Xq28. Analysis of the array revealed a missense mutation (c. 529TC [p. W177R]) in exon 3 of both the long-wavelength-sensitive (LW, red) and medium-wavelength-sensitive (MW, green) cone opsin genes that segregated with disease. Both exon 3 sequences were identical and were derived from the MW gene as a result of gene conversion. The amino acid W177 is highly conserved in visual and nonvisual opsins across species. We show that W177R in MW opsin and the equivalent W161R mutation in rod opsin result in protein misfolding and retention in the endoplasmic reticulum. We also demonstrate that W177R misfolding, unlike the P23H mutation in rod opsin that causes retinitis pigmentosa, is not rescued by treatment with the pharmacological chaperone 9-cis-retinal. Mutations in the LW/MW cone opsin gene array can, therefore, lead to a spectrum of disease, ranging from color blindness to progressive cone dystrophy (XLCOD5).

Published

2010

44. Variable retinal phenotypes caused by mutations in the X-linked photopigment gene array

Author

Eyal Banin, Liliana Mizrahi-Meissonnier, Dror Sharon, and Saul Merin

Subjects

Adult, Male, Opsin, Heterozygote, genetic structures, Adolescent, DNA Mutational Analysis, Molecular Sequence Data, Visual Acuity, Color Vision Defects, Biology, medicine.disease_cause, Nystagmus, Pathologic, Young Adult, Cone dystrophy, Genes, X-Linked, OPN1MW, medicine, Electroretinography, Humans, Color perception test, Amino Acid Sequence, Child, X-linked recessive inheritance, Genetics, Mutation, Color Perception Tests, medicine.diagnostic_test, Retinal Degeneration, Chromosome Mapping, Genetic Diseases, X-Linked, Middle Aged, medicine.disease, Molecular biology, Cone Opsins, eye diseases, Pedigree, Phenotype, OPN1LW, Child, Preschool, Jews, Female, sense organs, Visual Fields, Tomography, Optical Coherence

Abstract

PURPOSE. To examine the involvement of the long (L) and middle (M) wavelength-sensitive cone opsin genes in conedominated phenotypes. METHODS. Clinical and molecular analyses included family history, color vision testing, full-field electroretinography (ERG), linkage analysis, and mutation detection. RESULTS. Eighteen families were recruited that had X-linked retinal disease characterized by cone impairment in which affected males usually had nystagmus, reduced visual acuity, normal to subnormal rod ERG, and reduced or extinguished cone ERG responses. A search for mutations in the L-M pigment gene array revealed disease-causing mutations in six families. In two of them, novel mutations were identified: a large deletion affecting both opsin genes and a single L opsin gene harboring a likely pathogenic mutation, p.Val120Met. A third family carried a single hybrid gene with the p.Cys203Arg mutation. Patients from the three remaining families carried a single opsin gene harboring two similar rare haplotypes. Although the phenotype of members in one of the families was compatible with blue cone monochromacy (BCM), patients from the two other families, who shared an identical haplotype, had only reduced or even normal full-field cone ERGs, but maculopathy was evident. CONCLUSIONS. Novel and known mutations affecting the L-M opsin gene array were identified in families with X-linked cone-dominated phenotypes. The results show that different mutations in this gene array can cause a variety of phenotypes, including BCM, cone dystrophy, and maculopathy. Males with X-linked cone-dominated diseases should be routinely analyzed for mutations in the L-M opsin gene array. (Invest Ophthalmol Vis Sci. 2010;51:3884‐3892) DOI:10.1167/iovs.09-4592

Published

2010

45. A locus control region adjacent to the human red and green visual pigment genes

Author

John D. Gearhart, Jeremy Nathans, Yanshu Wang, Jennifer P. Macke, Brenda Klaunberg, Donald J. Zack, Shannath L. Merbs, and Jean Bennett

Subjects

genetic structures, Molecular Sequence Data, Mice, Transgenic, Locus (genetics), Biology, Eye, Conserved sequence, Mice, Transcription (biology), Sequence Homology, Nucleic Acid, Gene expression, Animals, Humans, Photoreceptor Cells, Gene, Locus control region, Base Sequence, General Neuroscience, Chromosome Mapping, Promoter, beta-Galactosidase, Molecular biology, Genes, OPN1LW, Cattle, sense organs, Chromosome Deletion, Retinal Pigments

Abstract

Deletion of sequences 5′ of the human red and green pigment gene array results in blue cone monochromacy, a disorder in which both red and green cone function are absent. To test whether these sequences are required for transcription of the adjacent visual pigment genes in cone photoreceptors, we produced transgenic mice carrying sequences upstream of the red and green pigment genes fused to a β-galactosidase reporter. The patterns of transgene expression indicate that the human sequences direct expression to both long and short wave-sensitive cones in the mouse retina and that a region between 3.1 kb and 3.7 kb 5′ of the red pigment gene transcription initiation site is essential for expression. Sequences within this region are highly conserved among humans, mice, and cattle, even though the latter two species have only a single visual pigment gene at this locus. These experiments suggest a model in which an interaction between the conserved 5′ region and either the red or the green pigment gene promoter determines which of the two genes a given cone expresses.

Published

1992

46. Defective colour vision associated with a missense mutation in the human green visual pigment gene

Author

Delwin T. Lindsey, Joris Winderickx, Samir S. Deeb, Elizabeth Sanocki, Davida Y. Teller, and Arno G. Motulsky

Subjects

Male, Opsin, X Chromosome, genetic structures, Molecular Sequence Data, Population, Locus (genetics), Biology, Arginine, Polymerase Chain Reaction, Protein Structure, Secondary, Choroideremia, Retinitis pigmentosa, Genetics, medicine, Humans, Point Mutation, Missense mutation, Amino Acid Sequence, Cysteine, education, education.field_of_study, Polymorphism, Genetic, Base Sequence, Point mutation, Rod Opsins, Chromosome Mapping, DNA, medicine.disease, eye diseases, Blotting, Southern, Oligodeoxyribonucleotides, OPN1LW, Color Perception

Abstract

All red/green colour vision defects described so far have been associated with gross rearrangements within the red/green opsin gene array (Xq28). We now describe a male with severe deuteranomaly without such a rearrangement. A substitution of a highly conserved cysteine by arginine at position 203 in the green opsins presumably accounted for his colour vision defect. Surprisingly, this mutation was fairly common (2%) in the population but apparently was not always expressed. In analogy with nonexpression of some 5'green-red hybrid genes in persons with normal colour vision, we suggest that failure of manifestation occurs when the mutant gene is located at a distal (3') position among several green opsin genes. This mutation might also predispose to certain X-linked retinal dystrophies.

Published

1992

47. Evaluation of the X-Linked High-Grade Myopia Locus (MYP1) with Cone Dysfunction and Color Vision Deficiencies

Author

Yi-Ju Li, Anuradha Bulusu, Marianne Schwartz, Stephan Züchner, Michel Michaelides, Terri L. Young, Anthony T. Moore, Ravikanth Metlapally, Catherine Bowes Rickman, Thomas Rosenberg, and David M. Hunt

Subjects

Male, Opsin, genetic structures, Genotype, Gene Dosage, Locus (genetics), Color Vision Defects, Biology, Article, Retinal Diseases, OPN1MW, Humans, Copy-number variation, RNA, Messenger, X-linked recessive inheritance, Genetics, Opsins, Reverse Transcriptase Polymerase Chain Reaction, Gene Expression Profiling, Membrane Proteins, Nucleic Acid Hybridization, Genetic Diseases, X-Linked, eye diseases, Pedigree, Nested gene, OPN1LW, Myopia, Degenerative, Retinal Cone Photoreceptor Cells, Female, sense organs

Abstract

Numerous genetic linkage studies have identified chromosomal regions associated with primarily familial development of myopia.1 In the present study, we evaluated pedigrees that mapped to the first identified locus for high myopia on chromosome X (MYP1, OMIM 310460).2 In a large pedigree reported in 1988, this locus was mapped to chromosome Xq27.3–28 by Schwartz et al.2–4 and Young et al.2–4 using restriction fragment-linked polymorphic markers. The family originated in Bornholm, Denmark, and the phenotype of Bornholm eye disease (BED) included high-grade myopia, amblyo-pia, optic nerve hypoplasia, subnormal dark-adapted electroretinographic (ERG) flicker function, and deuteranopia. In 2004, Young et al.4 reported another high-grade myopia phenotype in a family of Danish descent living in Minnesota that mapped to the Xq28 locus, with a similar phenotype of optic nerve hypoplasia with temporal pigmentary crescent, subnormal photopic ERG function, and protanopia rather than deuteranopia in the BED phenotype. We suggested that the phenotype was more consistent with an X-linked cone dysfunction than with simplex myopia. A recent replication report from the United Kingdom confirmed the X-linked cone dysfunction syndrome with an associated moderate to high myopia and protanopia phenotype.5 Although the X-linked myopia phenotypes are similar, a distinguishing feature is the type of color vision deficiency, which is deuteranopia in the BED pedigree and protanopia in the Minnesota and United Kingdom pedigrees. Interestingly, the visual cone pigment (opsin) genes, red (long wavelength [L]) and green (medium wavelength [M]), are present in tandem on the human X-chromosome at Xq28. In this opsin gene array, a single L, or red, gene is followed by one or more copies of the M, or green, gene in the normal color vision state.6,7 Alterations in this gene array with a red-green opsin hybrid gene in the first position or a green-red opsin hybrid in the second position are associated with protan and deutan color vision defects, respectively.7,8 Young et al.4 performed single-stranded conformational polymorphism analysis to determine the ratio of red to green promoters in the BED and Minnesota pedigrees. We previously determined that affected and unaffected males in both pedigrees had four and three opsin genes, respectively, and reported that known reported hybrid opsin genes are responsible for the respective color vision deficiencies.4 The opsin gene array represents a region of repetitive DNA segments termed segmental duplications. The segmental duplications involving opsin genes encompass the testis-expressed protein 28 gene (TEX28), also known as chromosome X open-reading frame 2 (CXorf2), a nested gene within the cone opsin pigment gene array.9 TEX28 is composed of five exons that almost span the entire distance between the protein-coding regions of the opsin genes and the transketolase-related type 1 gene (TKTL1), and it encodes a polypeptide of 410 amino acid residues (Fig. 1). Few studies of TEX28 have been reported in the literature, and its involvement in the X-linked myopia phenotypes is unknown.10,11 The reported number of normal repetitive copies of TEX28 is three, intercalated within and translated in the opposite (3′ to 5′) direction from the opsin gene array.9 Figure 1 Schematic representation of the arrangement of opsin gene array and TEX28 genes at the chromosome Xq28 locus (source, UCSC Genome Browser [http://genome.ucsc.edu/]). OPN1LW, red cone pigment gene; OPN1MW, green cone pigment gene; TKTL1, transketolase-related ... Because of the consistent color vision deficiencies in all reported MYP1 pedigrees, we hypothesized that the X-linked MYP1 myopia phenotype could be caused by TEX28 sequence alterations or copy number variation (CNV). This was determined using fine mapping array comparative genomic hybridization (array-CGH) and real-time quantitative polymerase chain reaction (RT-qPCR) assays. Sequence mutation screening, genetic association, and gene expression studies were also performed.

Published

2008

48. Different selective pressures shape the molecular evolution of color vision in chimpanzee and human populations

Author

Anne C. Stone, Brian C. Verrelli, George H. Perry, and Cecil M. Lewis

Subjects

genetic structures, Pan troglodytes, Color vision, Population, Single-nucleotide polymorphism, Biology, Balancing selection, Nucleotide diversity, Molecular evolution, Genetic variation, Genetics, Animals, Humans, Selection, Genetic, education, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Research Articles, education.field_of_study, Base Sequence, Color Vision, Rod Opsins, Genetic Variation, Biological Evolution, OPN1LW, Evolutionary biology, Sequence Alignment

Abstract

A population genetic analysis of the long-wavelength opsin (OPN1LW, "red") color vision gene in a global sample of 236 human nucleotide sequences had previously discovered nine amino acid replacement single nucleotide polymorphisms, which were found at high frequencies in both African and non-African populations and associated with an unusual haplotype diversity. Although this pattern of nucleotide diversity is consistent with balancing selection, it has been argued that a recombination "hot spot" or gene conversion within and between X-linked color vision genes alone may explain these patterns. The current analysis investigates a closely related primate with trichromatism to determine whether color vision gene amino acid polymorphism and signatures of adaptive evolution are characteristic of humans alone. Our population sample of 56 chimpanzee (Pan troglodytes) OPN1LW sequences shows three singleton amino acid polymorphisms and no unusual recombination or linkage disequilibrium patterns across the approximately 5.5-kb region analyzed. Our comparative population genetic approach shows that the patterns of OPN1LW variation in humans and chimpanzees are consistent with positive and purifying selection within the two lineages, respectively. Although the complex role of color vision has been greatly documented in primate evolution in general, it is surprising that trichromatism has followed very different selective trajectories even between humans and our closest relatives.

Published

2008

49. Blue Cone Monochromacy: Visual Function and Efficacy Outcome Measures for Clinical Trials

Author

Svetlana A. Yatsenko, Barbara J. Jennings, Alexander Sumaroka, Alessandro Iannaccone, Malgorzata Swider, Xunda Luo, Bernd Wissinger, Rebecca Sheplock, Lauren C. Ditta, Sharon B. Schwartz, Susanne Kohl, Artur V. Cideciyan, Samuel G. Jacobson, and Alejandro J. Roman

Subjects

Adult, Fovea Centralis, medicine.medical_specialty, Adolescent, Eye Movements, Light, genetic structures, Color vision, Science, Color Vision Defects, Dark Adaptation, Retinal Cone Photoreceptor Cells, Young Adult, BLUE CONE MONOCHROMACY, Retinal Diseases, Ophthalmology, Outcome Assessment, Health Care, Humans, Medicine, Child, Vision, Ocular, Aged, Clinical Trials as Topic, Multidisciplinary, business.industry, Fovea centralis, Middle Aged, medicine.disease, Cone Opsins, eye diseases, Clinical trial, medicine.anatomical_structure, OPN1LW, Child, Preschool, Visual Field Tests, sense organs, business, Photic Stimulation, Research Article, Retinopathy

Abstract

BackgroundBlue Cone Monochromacy (BCM) is an X-linked retinopathy caused by mutations in the OPN1LW / OPN1MW gene cluster, encoding long (L)- and middle (M)-wavelength sensitive cone opsins. Recent evidence shows sufficient structural integrity of cone photoreceptors in BCM to warrant consideration of a gene therapy approach to the disease. In the present study, the vision in BCM is examined, specifically seeking clinically-feasible outcomes for a future clinical trial.MethodsBCM patients (n = 25, ages 5-72) were studied with kinetic and static chromatic perimetry, full-field sensitivity testing, and eye movement recordings. Vision at the fovea and parafovea was probed with chromatic microperimetry.ResultsKinetic fields with a Goldmann size V target were generally full. Short-wavelength (S-) sensitive cone function was normal or near normal in most patients. Light-adapted perimetry results on conventional background lights were abnormally reduced; 600-nm stimuli were seen by rods whereas white stimuli were seen by both rods and S-cones. Under dark-adapted conditions, 500-nm stimuli were seen by rods in both BCM and normals. Spectral sensitivity functions in the superior retina showed retained rod and S-cone functions in BCM under dark-adapted and light-adapted conditions. In the fovea, normal subjects showed L/M-cone mediation using a 650-nm stimulus under dark-adapted conditions, whereas BCM patients had reduced sensitivity driven by rod vision. Full-field red stimuli on bright blue backgrounds were seen by L/M-cones in normal subjects whereas BCM patients had abnormally reduced and rod-mediated sensitivities. Fixation location could vary from fovea to parafovea. Chromatic microperimetry demonstrated a large loss of sensitivity to red stimuli presented on a cyan adapting background at the anatomical fovea and surrounding parafovea.ConclusionsBCM rods continue to signal vision under conditions normally associated with daylight vision. Localized and retina-wide outcome measures were examined to evaluate possible improvement of L/M-cone-based vision in a clinical trial.

Published

2015

50. X-linked cone dysfunction syndrome with myopia and protanopia

Author

John D. Mollon, K. Bradshaw, Michel Michaelides, David M. Hunt, Graham E. Holder, Samantha Johnson, Anthony T. Moore, and Matthew P. Simunovic

Subjects

Adult, Male, medicine.medical_specialty, Opsin, genetic structures, Adolescent, DNA Mutational Analysis, Color Vision Defects, Biology, Retinal Cone Photoreceptor Cells, Polymerase Chain Reaction, Molecular genetics, medicine, Electroretinography, Myopia, Humans, Child, Aged, Genetics, Chromosomes, Human, X, medicine.diagnostic_test, Rod Opsins, Genetic Diseases, X-Linked, Syndrome, medicine.disease, X-linked cone dysfunction syndrome with myopia, Pedigree, Ophthalmology, OPN1LW, Cone dysfunction syndrome, Child, Preschool, sense organs, Dichromacy

Abstract

Purpose To perform a detailed clinical, psychophysical, and molecular assessment of members of 4 families with an unusual X-linked cone dysfunction syndrome associated with myopia. Participants Affected and unaffected members of 4 British nonconsanguineous families. Methods Subjects underwent both detailed clinical examination and psychophysical testing. After informed consent was obtained, blood samples were taken for DNA extraction, and molecular genetic analysis was performed. The strategy for molecular analysis was to amplify the coding regions of the long and middle wavelength-sensitive cone opsin genes and the upstream locus control region by polymerase chain reaction and to examine these fragments for mutations by sequencing of DNA. Results The phenotype was almost identical in all 4 families, consisting of moderate to high myopia, astigmatism, moderately reduced acuity, and normal fundi. Electroretinography showed abnormal cone but normal rod responses. Psychophysical testing showed a selective impairment of long cones in combination with well-preserved middle cone and short cone function. There was no evidence to suggest that the phenotype was progressive. Molecular analysis of the X-linked opsin gene array in the 4 families indicated that affected males have inherited the same X-chromosome from their mother. In 2 families, a long/middle hybrid gene was detected. In a third family, the commonly described deleterious Cys203Arg amino acid substitution was identified in both the long and middle opsin genes. In the fourth family, the only abnormality was absence of a middle opsin exon 2; the cause of the protanopia in this family is uncertain. Conclusions The X-linked cone dysfunction syndrome associated with myopia and dichromacy described here has many similarities to Bornholm eye disease, a condition previously mapped to Xq28. Except for the Cys203Arg substitution in one family, no alterations in the opsin gene array were identified that could underlie the cone dysfunction. It is therefore possible that the cone dysfunction may have a genetic origin different from that of the dichromacy.

Published

2004