Atypical presentation of Oguchi disease with severe cystoid macular edema and compound heterozygous SAG pathogenic variants

Oguchi disease is a rare autosomal recessive retinal dystrophy, characterized by congenital stationary blindness and caused by pathogenic variants in SAG and GRK1 genes. The present study aimed to report an Italian patient affected by Oguchi disease, evaluated by means of a multimodal retinal imaging study and harboring two novel heterozygous pathogenic variants in the SAG gene. A 60-year-old female complaining congenital stationary night blindness was investigated through fundus photograph, optical coherence tomography (OCT), electroretinography (ERG), and genetic testing. Fundus examination showed a golden-grayish fundus aspect. The rod response of the scotopic ERG was undetectable and mixed rod-cone response was electronegative. Fundus photographs obtained in light and in prolonged dark-adapted conditions allowed to detect the Mizuo-Nakamura phenomenon. Light condition OCT over the abnormal retinal regions showed high-intensity areas in the outer photoreceptor segment layer, that reduced with prolonged dark adaption. Genetic testing identified two rare heterozygous sequence variants in the SAG gene: NM_000541.5:c.807delA p.(Glu270Lysfs*9) and NM_000541.5:c.1047-1G>C confirming the diagnosis of Oguchi disease. We identified the first Italian compound heterozygous patient harboring two novel alterations in the SAG gene (a frameshift deletion and a splicing variant). The involvement of the SAG gene in Oguchi disease is a common finding in Japanese population, but rarely identified in Caucasians. Clinical suspicion should prompt the molecular analysis of genes associated with this condition.

Congenital stationary night blindness (CSNB) is a group of genetically and clinically heterogeneous non-progressive retinal disorders and can be classified based on fundus abnormalities as found in Oguchi disease or fundus albipunctatus (FA) or based on the absence of severe fundus abnormalities but altered electroretinography (ERG) findings. Here, we report the clinical and genetic findings of 46 CSNB families, with 18 families showing fundus abnormalities and 28 families without fundus abnormalities but having an altered ERG, showing complete CSNB (cCSNB) and Riggs type CSNB. Ophthalmic examinations including full-field ERG recordings, colour vision test, optical coherence tomography and fundus autofluorescence were performed and candidate genes for CSNB were screened by panel-based next-generation sequencing using an Illumina MiSeq platform. Subsequently, Sanger sequencing was performed to validate the identified variants and to confirm segregation with the phenotype in available family members. In 69% (11/16) of the Oguchi patients', pathogenic variants were found in SAG and GRK1, with p.(R292*) and p.(D537Vfs*7) variants being the most frequent mutations identified in this cohort in the two genes, respectively. A likely pathogenic variant p.(G238A) in RDH5 was identified in one of the two FA patients. In 92% of the CSNB (26/28) families without fundus abnormalities, pathogenic variants were found in NYX, leading to X-linked cCSNB; in GRM6, TRPM1, GPR179, LRIT3, leading to autosomal recessive cCSNB and in GNAT1, leading to autosomal recessive Riggs type CSNB. No significant copy number variants were identified. Combing this study with our previous report on CSNB from India, the most prevalent gene defects were variants in TRPM1 (37%) followed by GRM6 (32%) > NYX (10%) > SLC24A1 (5%) > GPR179 (5%), GNAT1 (3%) and LRIT3 (3%). In the current study, which included Oguchi disease and FA families as well, variants in SAG (38%) and GRK1 (31%) were identified in the Oguchi disease cases, and in the RDH5 gene in one of the two (50%) FA cases. Unsolved 8/56 (14%) (combined cohorts) cases may harbour variants in novel genes or intronic variants or structural variants undetectable by the screening method used herein.

Congenital stationary night blindness (CSNB) is a clinically and genetically heterogeneous inherited retinal disorder (IRD), and in many complete CSNB (cCSNB) cases, the underlying genetic cause remains unknown. Uncovering the genetic defects of IRDs helps to refine diagnostic methods and supports the development of specific therapeutic approaches. To describe the phenotype and the underlying gene defect in patients with cCSNB from 2 unrelated families. This retrospective case series was conducted from January 2023 to July 2025. Data for 3 patients from cohorts of genetically unsolved IRD cases in France (n = 140 for CSNB) and the Netherlands (n = 2730 for IRD) were analyzed clinically and genetically. Complete ocular examination, including multimodal retinal imaging and full-field electroretinography (ffERG) incorporating the International Society for Clinical Electrophysiology of Vision standards and multimodal retinal imaging, were performed. Gene defects were identified by genome sequencing (GS) and exome sequencing (ES). The main outcome was a gene defect, EGFLAM, underlying cCSNB. Measures included phenotyping, GS, ES, Sanger sequencing, and cosegregation analysis. The series included 3 patients from 2 unrelated families of Moroccan ancestry showing high myopia, reduced visual acuity, and night blindness. Retinal imaging depicted myopic changes. ffERG revealed electronegative Schubert-Bornschein configuration in keeping with cCSNB with ON-bipolar cell dysfunction. Patients were lacking pathogenic variants in known genes implicated in IRDs, including CSNB. Two different homozygous pathogenic variants, c.1563_1566del, p.(Val522Glufs*18) and c.1795C>T, p.(Arg599*) in EGFLAM were identified by ES and GS. The corresponding protein is localized in the outer plexiform layer and important for ON-bipolar cell signaling in the retina. This case series reports on a gene defect in EGFLAM implicated in human cCSNB. Clinicians should be aware about this association and consider including EGFLAM in diagnostic gene panels for IRDs. This discovery may lead to faster and more accurate diagnosis of cCSNB and genetic counseling, as well as a pathway for developing therapies.

Congenital stationary night blindness (CSNB) is a rare group of genetically inherited retinal disorders that are present from birth and do not show progressive characteristics. It is typically accompanied by symptoms such as night blindness, photophobia, myopia, nystagmus, and strabismus. CSNB is classified into subtypes based on different electrophysiological findings and inheritance patterns. Cases with a normal fundus appearance are categorized into Riggs type and Schubert-Bornschein type (which includes complete and incomplete subtypes) based on electroretinographic findings, while abnormal fundus appearance characterizes forms such as fundus albipunctatus (FA) and Oguchi disease. The genetic variations responsible for CSNB differ according to its subtypes. Riggs type CSNB is commonly associated with mutations in the PDE6B, RHO, GNAT1, and SLC24A1 genes. Complete CSNB is linked to mutations in GRM6, TRPM1, GPR179, LRIT3, and NYX genes, whereas incomplete CSNB involves mutations in CABP4, CACNA2D4, and CACNA1F. In FA, which presents with an abnormal fundus, mutations are often found in the RDH5, RLBP1, RPE65, and LRAT genes. Oguchi disease is associated with mutations in the SAG and GRK1 genes. Most of these genes are related to retinal photoreceptors, bipolar cells, or proteins involved in the retinoid cycle and play roles in signal transmission or the visual cycle.

P3-09-05: Clinical outcome of patients with advanced triple negative breast cancer with germline and somatic variants in homologous recombination gene

Background The majority of missense variants in clinical genetic tests are classified as variants of uncertain significance. Prior research has shown that the deleterious effects and the subsequent molecular consequence of variants are often conserved among paralogous protein sequences within a gene family. Here, we systematically quantified on an exome-wide scale if the existence of pathogenic variants in paralogous genes at a conserved position could serve as evidence for the pathogenicity of a new variant. For the gene family of voltage-gated sodium channels where variants and expert-curated clinical phenotypes were available, we also assessed whether phenotype patterns of multiple disorders for each gene were also conserved across variant positions within the gene family. Methods We developed a framework that assesses the presence of pathogenic missense variants located in conserved residues across paralogous genes. We systematically mapped 2.5 million pathogenic and general population variants from the ClinVar, HGMD, and gnomAD databases onto a total of 9,990 genes and aligned them by gene families. We evaluated the quantity of classifiable amino acids by utilizing pathogenic variants identified in databases alone and then compared this assessment to the inclusion of paralogous pathogenic variants. We validated and quantified the evidence of conserved pathogenic paralogous variants in variant pathogenicity classification. Results Considering conserved pathogenic variants in paralogous genes, increased the number of classifiable variants 2.8-fold across the exome, compared to pathogenic variants in the gene of interest alone. The presence of a pathogenic variant in a paralogous gene is associated with a positive likelihood ratio of 8.32 for variant pathogenicity. The likelihood ratio was gene family-specific. Across ten genes encoding voltage-gated sodium channels and 22 expert-curated disorders, we identified cross-paralog correlated phenotypes based on 3D structure spatial position. For example, the established loss-of-function disorders SCN1A-associated Dravet syndrome, SCN2A-associated autism, SCN5A-associated Brugarda Syndrome, and SCN8A-associated neurodevelopmental disorder without seizures were correlated in their spatial variant position on structure. Finally, we show that phenotype integration in paralog variant selection improves variant classification. Conclusion Our results show that paralogous variants, in particular with phenotype information can enhance our understanding of variant effects.

Endometrial cancer has been associated with pathogenic variants in mismatch repair (MMR) genes, especially in the context of the hereditary Lynch Syndrome. More recently, pathogenic variants in genes of homology‐directed repair (HDR) have also been suggested to contribute to a subset of endometrial cancers. In the present hospital‐based study, we investigated the relative distribution of pathogenic MMR or HDR gene variants in a series of 342 endometrial cancer patients from the Oncology Clinic in Almaty, Kazakhstan. In comparison, we also sequenced 178 breast cancer patients from the same population with the same gene panel. Identified variants were classified according to ClinVar, ESM1b, and AlphaMissense prediction tools. We found 10 endometrial cancer patients (2.9%) carrying pathogenic or likely pathogenic variants in MMR genes (7 MSH6, 1 MSH2, 2 MUTYH), while 14 endometrial cancer patients (4.1%) carried pathogenic variants in HDR genes (4 BRCA2, 3 BRCA1, 3 FANCM, 2 SLX4, 1 BARD1, 1 BRIP1). In the breast cancer series, we found 8 carriers (4.5%) of pathogenic or likely pathogenic variants in MMR genes (2 MSH2, 2 MSH6, 4 MUTYH) while 12 patients (6.7%) harbored pathogenic or likely pathogenic HDR gene variants (5 BRCA1, 3 BRCA2, 1 BRIP1, 1 ERRC4, 1 FANCM, 1 SLX4). One patient who developed breast cancer first and endometrial cancer later carried a novel frameshift variant in MSH6. Our results indicate that MMR and HDR gene variants with predicted pathogenicity occur at substantial frequencies in both breast and endometrial cancer patients from the Kazakh population.

SummaryBackgroundLynch syndrome is a rare familial cancer syndrome caused by pathogenic variants in the mismatch repair genes MLH1, MSH2, MSH6, or PMS2, that cause predisposition to various cancers, predominantly colorectal and endometrial cancer. Data are emerging that pathogenic variants in mismatch repair genes increase the risk of early-onset aggressive prostate cancer. The IMPACT study is prospectively assessing prostate-specific antigen (PSA) screening in men with germline mismatch repair pathogenic variants. Here, we report the usefulness of PSA screening, prostate cancer incidence, and tumour characteristics after the first screening round in men with and without these germline pathogenic variants.MethodsThe IMPACT study is an international, prospective study. Men aged 40–69 years without a previous prostate cancer diagnosis and with a known germline pathogenic variant in the MLH1, MSH2, or MSH6 gene, and age-matched male controls who tested negative for a familial pathogenic variant in these genes were recruited from 34 genetic and urology clinics in eight countries, and underwent a baseline PSA screening. Men who had a PSA level higher than 3·0 ng/mL were offered a transrectal, ultrasound-guided, prostate biopsy and a histopathological analysis was done. All participants are undergoing a minimum of 5 years' annual screening. The primary endpoint was to determine the incidence, stage, and pathology of screening-detected prostate cancer in carriers of pathogenic variants compared with non-carrier controls. We used Fisher's exact test to compare the number of cases, cancer incidence, and positive predictive values of the PSA cutoff and biopsy between carriers and non-carriers and the differences between disease types (ie, cancer vs no cancer, clinically significant cancer vs no cancer). We assessed screening outcomes and tumour characteristics by pathogenic variant status. Here we present results from the first round of PSA screening in the IMPACT study. This study is registered with ClinicalTrials.gov, NCT00261456, and is now closed to accrual.FindingsBetween Sept 28, 2012, and March 1, 2020, 828 men were recruited (644 carriers of mismatch repair pathogenic variants [204 carriers of MLH1, 305 carriers of MSH2, and 135 carriers of MSH6] and 184 non-carrier controls [65 non-carriers of MLH1, 76 non-carriers of MSH2, and 43 non-carriers of MSH6]), and in order to boost the sample size for the non-carrier control groups, we randomly selected 134 non-carriers from the BRCA1 and BRCA2 cohort of the IMPACT study, who were included in all three non-carrier cohorts. Men were predominantly of European ancestry (899 [93%] of 953 with available data), with a mean age of 52·8 years (SD 8·3). Within the first screening round, 56 (6%) men had a PSA concentration of more than 3·0 ng/mL and 35 (4%) biopsies were done. The overall incidence of prostate cancer was 1·9% (18 of 962; 95% CI 1·1–2·9). The incidence among MSH2 carriers was 4·3% (13 of 305; 95% CI 2·3–7·2), MSH2 non-carrier controls was 0·5% (one of 210; 0·0–2·6), MSH6 carriers was 3·0% (four of 135; 0·8–7·4), and none were detected among the MLH1 carriers, MLH1 non-carrier controls, and MSH6 non-carrier controls. Prostate cancer incidence, using a PSA threshold of higher than 3·0 ng/mL, was higher in MSH2 carriers than in MSH2 non-carrier controls (4·3% vs 0·5%; p=0·011) and MSH6 carriers than MSH6 non-carrier controls (3·0% vs 0%; p=0·034). The overall positive predictive value of biopsy using a PSA threshold of 3·0 ng/mL was 51·4% (95% CI 34·0–68·6), and the overall positive predictive value of a PSA threshold of 3·0 ng/mL was 32·1% (20·3–46·0).InterpretationAfter the first screening round, carriers of MSH2 and MSH6 pathogenic variants had a higher incidence of prostate cancer compared with age-matched non-carrier controls. These findings support the use of targeted PSA screening in these men to identify those with clinically significant prostate cancer. Further annual screening rounds will need to confirm these findings.FundingCancer Research UK, The Ronald and Rita McAulay Foundation, the National Institute for Health Research support to Biomedical Research Centres (The Institute of Cancer Research and Royal Marsden NHS Foundation Trust; Oxford; Manchester and the Cambridge Clinical Research Centre), Mr and Mrs Jack Baker, the Cancer Council of Tasmania, Cancer Australia, Prostate Cancer Foundation of Australia, Cancer Council of Victoria, Cancer Council of South Australia, the Victorian Cancer Agency, Cancer Australia, Prostate Cancer Foundation of Australia, Asociación Española Contra el Cáncer (AECC), the Instituto de Salud Carlos III, Fondo Europeo de Desarrollo Regional (FEDER), the Institut Català de la Salut, Autonomous Government of Catalonia, Fundação para a Ciência e a Tecnologia, National Institutes of Health National Cancer Institute, Swedish Cancer Society, General Hospital in Malmö Foundation for Combating Cancer.

ACMG SF v3.0 list for reporting of secondary findings in clinical exome and genome sequencing: a policy statement of the American College of Medical Genetics and Genomics (ACMG)

Background and Aims Autosomal dominant tubulointerstitial kidney disease (ADTKD) due to pathogenic variants in the MUC1 gene is difficult to diagnose since these variants lie in a large variable number tandem repeats (VNTR) and require specialized genetic testing, such as SNaPshot minisequencing. We recently developed a computational pipeline, VNtyper, for easier reliable detection of MUC1 VNTR pathogenic variants and have applied this tool to a large cohort of patients with various phenotypes of kidney disease. The aim of this study is to clinically describe patients in whom MUC1 pathogenic variants were unexpectedly detected with the help of VNtyper. Method We applied a computational pipeline, VNtyper, to a large cohort of patients with suspected hereditary kidney disease referred for genetic testing, regardless of their phenotype. This cohort included patients evaluated from 2017 to 2023 in the Molecular Genetics Department of Necker-Enfants Malades Hospital (Paris, France). Clinical characteristics were collected from patients in whom we detected new MUC1 VNTR pathogenic variants. Results 44 out of 3735 patients tested (1.2%) were newly diagnosed with a MUC1 pathogenic variant. Of these patients, ADTKD was clinically suspected in only 31 out of 44 patients (70%). In 2 patients, there was a pathogenic variant in another gene that could explain the phenotype, in addition to the MUC1 pathogenic variant. In fact, one 52-year-old patient had polycystic kidneys, nephrolithiasis, hematuria and normal kidney function. Her mother also had kidney cysts with absence of chronic kidney disease (CKD). This patient had a pathogenic variant in IFT140 gene (c.2399+1G>T) which could explain her autosomal dominant polycystic kidney disease (ADPKD) phenotype. Whether the MUC1 variant contributes to her disease remains unclear, especially seeing as her kidney function is normal at the age of 52 years. On the other hand, one patient had kidney cysts discovered at 3 days of age. A heterozygous HNF1B deletion was detected which could explain the phenotype. The following detection of a pathogenic MUC1 variant was thus an incidental finding and seemed de novo, although parents declined to get tested. These incidental findings can be challenging, especially when it comes to counselling and follow-up. There was no family history of kidney disease in 7 out of 44 patients (16%), and in one patient, we were able to confirm de novo disease since her parents were tested and were negative. It was unfortunately not possible to get DNA from the parents of the other patients. This is the first case of proven de novo ADTKD-MUC1 described to our knowledge. De novo variants in ADTKD-MUC1 are not surprising since the 7C stretch found in VNTR is a hotspot for mutagenesis. Interestingly, these patients seemed to have a more severe clinical presentation with an early onset of disease (median age at diagnosis 28 years [18, 32]). However, this could be due to a selection bias. In fact, young age of onset of CKD may have prompted clinicians to refer these patients for genetic testing despite negative family history, whereas older patients with possible ADTKD-MUC1 and no family history of kidney disease might be presumed to have another etiology of CKD. One way to confirm this would be to test a large cohort of patients with CKD from unknown etiology with no family history of CKD. Considering the nonspecific clinical manifestations of ADTKD-MUC1 and the phenotypic variability, it has previously been suggested that the most important clue to diagnosis is the presence of CKD in first-degree family. The possibility of de novo cases makes the clinical diagnosis of ADKTD-MUC1 even more challenging. Conclusion With VNtyper, we were able to diagnose new cases of ADTKD-MUC1 in a large cohort of patients with various phenotypes, with a significant prevalence of 1.2%. ADTKD-MUC1 was not suspected in 30% of these patients who would have maybe never been diagnosed otherwise. This is also the first study in which we describe a proven de novo case of ADTKD-MUC1. Pathogenic variants in the MUC1 gene should thus be in the differential diagnosis of all unspecified CKD, even if there is no family history since de novo variants are also possible.

Many common inherited retinal diseases are not easily treated with gene therapy. Gene editing with base editors may allow the targeted repair of single-nucleotide transition variants in DNA and RNA. It is unknown how many patients have pathogenic variants that are correctable with a base editing strategy. To assess the prevalence and spectrum of pathogenic single-nucleotide variants amenable to base editing in common large recessively inherited genes that are associated with inherited retinal degeneration. In this retrospective cross-sectional study, nonidentifiable records of patients with biallelic pathogenic variants of genes associated with inherited retinal degeneration between July 2013 and December 2019 were analyzed using data from the Oxford University Hospitals Medical Genetics Laboratories, the Leiden Open Variation Database, and previously published studies. Six candidate genes (ABCA4, CDH23, CEP290, EYS, MYO7A, and USH2A), which were determined to be the most common recessive genes with coding sequences not deliverable in a single adeno-associated viral vector, were examined. Data were analyzed from April 16 to May 11, 2020. Proportion of alleles with a pathogenic transition variant that is potentially correctable with a base editing strategy and proportion of patients with a base-editable allele. A total of 12 369 alleles from the Leiden Open Variation Database and 179 patients who received diagnoses through the genetic service of the Oxford University Hospitals Medical Genetics Laboratories were analyzed. Editable variants accounted for 53% of all pathogenic variants in the candidate genes contained in the Leiden Open Variation Database. The proportion of pathogenic alleles that were editable varied by gene; 63.1% of alleles in ABCA4, 62.7% of alleles in CDH23, 53.8% of alleles in MYO7A, 41.6% of alleles in CEP290, 37.3% of alleles in USH2A, and 22.2% of alleles in EYS were editable. The 5 most common editable pathogenic variants of each gene accounted for a mean (SD) of 19.1% (9.5%) of all pathogenic alleles within each gene. In the Oxford cohort, 136 of 179 patients (76.0%) had at least 1 editable allele. A total of 53 of 107 patients (49.5%) with biallelic pathogenic variants in the gene ABCA4 and 16 of 56 patients (28.6%) with biallelic pathogenic variants in the gene USH2A had 1 of the 5 most common editable alleles. This study found that pathogenic variants amenable to base editing commonly occur in inherited retinal degeneration. These findings, if generalized to other cohorts, provide an approach for developing base editing therapies to treat retinal degeneration not amenable to gene therapy.

Germline pathogenic variants in CDKN2A are well established as an underlying cause of familial malignant melanoma. While pathogenic variants in other genes have also been linked to melanoma, most familial cases remain unexplained. We assessed pathogenic germline variants in 360 cancer-related genes in 56 Norwegian melanoma-prone families. The index cases were selected based on familial history of melanoma and/or multiple primary melanomas, along with previous negative tests for pathogenic CDKN2A variants. We found 6 out of 56 index individuals to carry germline pathogenic or likely pathogenic variants in BRCA2, MRE11, ATM, MSH2, CHEK2, and AR. One family member with melanoma (not index case) carried a pathogenic variant in MAP3K6. In addition, we found a high fraction of variants previously considered benign and/or as variants of uncertain significance in xeroderma pigmentosum-related genes. In particular, XPCL48F was found in 8 indexes; thus, the allele fraction (0.07) was significantly higher than in comparable healthy populations (0.02-0.03; P-values from 0.007 to 0.014). In conclusion, we found that several melanoma-prone families have pathogenic variants in genes not usually linked to melanoma.

The presence of germline pathogenic variants in CDKN2A is a well-established underlying cause of familial malignant melanoma. While pathogenic variants in several other genes have also been linked to melanoma development, many familial cases remain unexplained. We analyzed for pathogenic germline variants in a panel of 360 cancer related genes in a set of 56 Norwegian melanoma prone families. The index cases and families were selected based on familial history of melanoma and/or multiple primary melanomas in the same individual, along with previous negative tests for pathogenic CDKN2A variants. We found 6 out of 56 index individuals to carry germline pathogenic or likely pathogenic variants. These variants were found in BRCA2, MRE11, ATM, MSH2, CHEK2 and AR. In addition, one family member with a melanoma diagnosis (not index case) carried a pathogenic variant in MAP3K6. In genes typically linked to xeroderma pigmentosum, we found a high fraction of variants previously considered benign and/or as variants of uncertain significance. In particular the XPCL48F variant was found in 8 out of 56 indexes, thus, the allele fraction (0.07) was significantly higher than in comparable healthy populations (p-values from 0.007 to 0.014). Similarly, we found presumed benign or uncertain variants in MC1R to be significantly enriched or numerically higher in index cases versus comparable healthy populations (p-values from 0.009 to 0.1). The common MC1RArg151Cys variant was highly enriched in our cohort (p=0.001).In conclusion, we found that several melanoma prone families harbored pathogenic variants in genes not usually linked to melanoma. Citation Format: Stian Knappskog, Gjertrud T. Iversen, Marie Loeng, Amalie L. Holth, Per E. Lonning, Jurgen Geisler. Germline variants in CDKN2A wild-type melanoma prone families [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 5050.

Lupus nephritis is a rare immunological disorder. Genetic factors are considered important in its causation. We aim to systematically investigate the rare pathogenic gene variants in patients with lupus nephritis. Whole-exome sequencing was used to screen pathogenic gene variants in 1886 probands with lupus nephritis. Variants were interpreted on the basis of known pathogenic variants or the American College of Medical Genetics and Genomics guidelines and studied by functional analysis, including RNA sequencing, quantitative PCR, cytometric bead array, and Western blotting. Mendelian form of lupus nephritis was confirmed in 71 probands, involving 63 variants in 39 pathogenic genes. The detection yield was 4%. The pathogenic genes enriched in nuclear factor kappa-B (NF-κB), type I interferon, phosphatidylinositol-3-kinase/serine/threonine kinase Akt (PI3K/AKT), Ras GTPase/mitogen-activated protein kinase (RAS/MAPK), and Janus kinase/signal transducer and activator of transcription (JAK/STAT) pathways. Clinical manifestation patterns were diverse among different signaling pathways. More than 50% of the pathogenic gene variants were reported to be associated with lupus or lupus nephritis for the first time. The identified pathogenic gene variants of lupus nephritis overlapped with those of autoinflammatory and immunodeficiency diseases. Inflammatory signatures, such as cytokine levels of IL-6, IL-8, IL-1 β , IFN α , IFN γ , and IP10 in serum and transcriptional levels of interferon-stimulated genes in blood, were significantly higher in patients with pathogenic gene variants compared with controls. The overall survival rate of patients with pathogenic gene variants was lower than those without pathogenic gene variants. A small fraction of patients with lupus nephritis had identifiable pathogenic gene variants, primarily in NF-κB, type I interferon, PI3K/AKT, JAK/STAT, RAS/MAPK, and complement pathways.

Oguchi disease is a rare autosomal recessive form of congenital stationary night blindness (CSNB) characterized by specific features such as golden-brown discoloration of the fundus called Mizuo-Nakamura phenomenon which is distinguishable by fundoscopy, and retinography. Clinical diagnosis is confirmed through genetic test. Two known genes in pathogenesis of Oguchi disease are SAG and GRK1. A 35-year-old Iranian male exhibiting the clinical features of congenital stationary night blindness, was referred to the genetic clinic of Dr. Farhud, Tehran, Iran in 2012 and examined. Ophthalmic examination including slit-lamp biomicroscopy, perimetry and funduscopy was performed. Additionally, the full-field electroretinography and molecular testing for congenital stationary night blindness were performed. Molecular genetic tests, including the analysis of GSK1 and SAG genes exon-intron boundaries were performed for this patient and his family. According to the sequencing results, we did not find any mutation in GSK1 gene. However, a new homozygote mutation at location chr2:233320735, c.517delC, p.P96LfsX28 was identified in exon four of SAG gene. This deletion causes a frame shift mutation, and premature stop codon that results in deletion of about 281 amino acid residues of S-antigen visual arrestin protein (from entire C-terminal). This mutation was also found in patient's parents and one of his sister as heterozygote form. This is the first molecular evidence for SAG gene mutation in an Iranian family affected with Oguchi disease type 1. The identification of the new c.517delC, p.P96LfsX28 mutation in this family with Oguchi disease can confirm the pathogenicity of this variant.