Genetic analysis identified the presence of novel double heterozygous of c.361G>A; p.E121K in NR2E3, a gene responsible for enhanced S-cone syndrome (ESCS; OMIM #268100) and c.244A>G; p.K82E in OPN1LW, a gene responsible for blue cone monochromacy (BCM; OMIM#303700).
This paper reviews the published histopathologic findings of patients with retinitis pigmentosa (RP) or an allied disease in whom the responsible gene defect was identified, including 10 cases with dominant RP (cases with mutations in RHO, PRPC8, and RP1), three with dominant spinocerebellar ataxia (SCA7), three X-linked RP carrier females (RPGR), two with congenital retinal blindness (AIPL1 and RPE65), two with mitochondrial encephalomyopathy overlap syndrome (MTTL1), and one case each with dominant cone degeneration (GCAP1), X-linked cone degeneration (RCP), enhanced S-cone syndrome (NR2E3), and dominant late-onset retinal degeneration (CTRP5).
This paper reviews the published histopathologic findings of patients with retinitis pigmentosa (RP) or an allied disease in whom the responsible gene defect was identified, including 10 cases with dominant RP (cases with mutations in RHO, PRPC8, and RP1), three with dominant spinocerebellar ataxia (SCA7), three X-linked RP carrier females (RPGR), two with congenital retinal blindness (AIPL1 and RPE65), two with mitochondrial encephalomyopathy overlap syndrome (MTTL1), and one case each with dominant cone degeneration (GCAP1), X-linked cone degeneration (RCP), enhanced S-cone syndrome (NR2E3), and dominant late-onset retinal degeneration (CTRP5).
This paper reviews the published histopathologic findings of patients with retinitis pigmentosa (RP) or an allied disease in whom the responsible gene defect was identified, including 10 cases with dominant RP (cases with mutations in RHO, PRPC8, and RP1), three with dominant spinocerebellar ataxia (SCA7), three X-linked RP carrier females (RPGR), two with congenital retinal blindness (AIPL1 and RPE65), two with mitochondrial encephalomyopathy overlap syndrome (MTTL1), and one case each with dominant cone degeneration (GCAP1), X-linked cone degeneration (RCP), enhanced S-cone syndrome (NR2E3), and dominant late-onset retinal degeneration (CTRP5).
This paper reviews the new finding of LCA from mutations of CRB1 and discusses the molecular basis of X-linked blue monochromacy, autosomal recessive congenital achromatopsia from mutations of the genes for ACHM2 (CNGA3) and ACHM3 (CNGB3), X-linked congenital stationary night blindness (CSNB) from mutations of CACNA1F (incomplete CSNB) and NYX (complete CSNB), and the enhanced S-cone syndrome from mutation of the developmental gene, NR2E3 at 15q23, which appears to regulate the development of M- and L-cones from S-cones.
This paper reviews the new finding of LCA from mutations of CRB1 and discusses the molecular basis of X-linked blue monochromacy, autosomal recessive congenital achromatopsia from mutations of the genes for ACHM2 (CNGA3) and ACHM3 (CNGB3), X-linked congenital stationary night blindness (CSNB) from mutations of CACNA1F (incomplete CSNB) and NYX (complete CSNB), and the enhanced S-cone syndrome from mutation of the developmental gene, NR2E3 at 15q23, which appears to regulate the development of M- and L-cones from S-cones.
This paper reviews the new finding of LCA from mutations of CRB1 and discusses the molecular basis of X-linked blue monochromacy, autosomal recessive congenital achromatopsia from mutations of the genes for ACHM2 (CNGA3) and ACHM3 (CNGB3), X-linked congenital stationary night blindness (CSNB) from mutations of CACNA1F (incomplete CSNB) and NYX (complete CSNB), and the enhanced S-cone syndrome from mutation of the developmental gene, NR2E3 at 15q23, which appears to regulate the development of M- and L-cones from S-cones.
This paper reviews the new finding of LCA from mutations of CRB1 and discusses the molecular basis of X-linked blue monochromacy, autosomal recessive congenital achromatopsia from mutations of the genes for ACHM2 (CNGA3) and ACHM3 (CNGB3), X-linked congenital stationary night blindness (CSNB) from mutations of CACNA1F (incomplete CSNB) and NYX (complete CSNB), and the enhanced S-cone syndrome from mutation of the developmental gene, NR2E3 at 15q23, which appears to regulate the development of M- and L-cones from S-cones.
In 94% of a cohort of ESCS probands we found mutations in NR2E3 (also known as PNR), which encodes a retinal nuclear receptor recently discovered to be a ligand-dependent transcription factor.
This report expands the spectrum of NRL recessive mutations, as well as the genetic spectrum of ESCS, and indicates a new syndrome of OPMD with an ESCS-like phenotype.
The neural retina leucine zipper transcription factor-knockout (Nrl(-/-)) mouse model demonstrates many phenotypic features of human ESCS, including unstable S-cone-positive photoreceptors.
The neural retina leucine zipper transcription factor-knockout (Nrl(-/-)) mouse model demonstrates many phenotypic features of human ESCS, including unstable S-cone-positive photoreceptors.
Loss-of-function NRL alleles have not been described previously in humans, but since the same mutation was present in unaffected family members, it raises the possibility that the abnormal ESCS phenotype in Patient A may result from a digenic mechanism, with a heterozygous NRL mutation and a mutation in another unknown gene.
Mutations in NR2E3 typically lead to recessive enhanced S-cone syndrome (ESCS), where affected individuals show higher sensitivity to short wavelength light and early onset rod dysfunction.
Genetic analysis identified the presence of novel double heterozygous of c.361G>A; p.E121K in NR2E3, a gene responsible for enhanced S-cone syndrome (ESCS; OMIM #268100) and c.244A>G; p.K82E in OPN1LW, a gene responsible for blue cone monochromacy (BCM; OMIM#303700).
Electroretinography responses of both patients were dominated by short-wavelength-sensitive mechanisms, with no detectable rod function, similar to the ERG responses of individuals with enhanced S-cone syndrome (ESCS) due to NR2E3 mutations.