Abstract
The ATP-binding cassette subfamily 4 (ABCA4), a transporter, is localized within the photoreceptors of the retina, and its genetic variants cause retinal dystrophy. Despite the clinical importance of the ABCA4 transporter, a few studies have investigated the function of each variant. In this study, we functionally characterized ABCA4 variants found in Korean patients with Stargardt disease or variants of the ABCA4 promoter region. We observed that four missense variants—p.Arg290Gln, p.Thr1117Ala, p.Cys1140Trp, and p.Asn1588Tyr—significantly decreased ABCA4 expression on the plasma membrane, which could be due to intracellular degradation. There are four major haplotypes in the ABCA4 proximal promoter. We observed that the H1 haplotype (c.-761C>A) indicated significantly increased luciferase activity compared to that of the wild-type, whereas the H3 haplotype (c.-1086A>C) indicated significantly decreased luciferase activity (P < 0.01 and 0.001, respectively). In addition, c.-900A>T in the H2 haplotype exhibited significantly increased luciferase activity compared with that of the wild-type. Two transcription factors, GATA-2 and HLF, were found to function as enhancers of ABCA4 transcription. Our findings suggest that ABCA4 variants in patients with Stargardt disease affect ABCA4 expression. Furthermore, common variants of the ABCA4 proximal promoter alter the ABCA4 transcriptional activity, which is regulated by GATA-2 and HLF transcription factors.
Similar content being viewed by others
Introduction
The ATP-binding cassette sub-family A member 4 (ABCA4) (also known as Rim protein or ABCR) is an ABC transporter1,2. It consists of 2,273 amino acids and is expressed in the rim region of rod photoreceptor outer segment disc membranes and in foveal and peripheral cone photoreceptor outer segment disc membranes3. Unlike many ABC transporters, which function as efflux pumps, ABCA4 transporter is a unique import pump4. It transports all-trans-retinal (ATR) or N-retinylidene-phosphatidylethanolamine (PE) from the luminal side to the cytoplasmic side. Functional deficiency of this transporter leads to accumulation of ATR or N-retinylidene-PE in photoreceptors and retinal pigment epithelium (RPE) cells When N-retinylidene-PE accumulates, the production of N-retinylidene-N-retinylethanolamine (A2E) increases. Further, A2E has several detrimental effects on RPE cells; RPE cells deaths is induced through the generation of reactive oxygen species and dysfunction of lysosomal degradation. Ultimately, photoreceptors are lost5.
Many genetic variants of ABCA4 are associated with various forms of retinal dystrophy, including Stargardt disease, retinitis pigmentosa, and cone-rod dystrophy1,6,7,8,9,10,11,12. In patients with ABCA4-associated retinopathy, the characteristic clinical symptoms of the disease such as macular affection, fundus flecks, and peripapillary sparing can be observed. The severity of these clinical symptoms can vary depending on the stage of the disease13. ABCA4 variants have been extensively studied in diverse populations and disease-causing ABCA4 variants vary according to race or ethnicity13.
Functional studies of the ABCA4 missense variants have been reported. For example, the transport activities of p.Gly863Ala, p.Asn965Ser, p.Lys969Met, and p.Lys1978Met variants found in Stargardt disease were significantly reduced compared with that of the wild-type ABCA4 following overexpression in HEK-293T cells4.
Although the missense variants of ABCA4 account for the largest proportion of disease-causing variants, recent studies have indicated that variants in other areas of the gene also play an important role as disease-causing variants13. For example, 64 non-canonical splice site variants indicated splicing defects, such as exon skipping, exon elongation, or intron retention, and many of these variants resulted in 100% aberrantly spliced RNA in previous studies14,15,16,17. Furthermore, 20 variants among 35 deep-intronic or near-exon variants were reported to have deleterious or severe effects in ABCA4-associated retinopathy, based on in vitro splice assays and analysis of photoreceptor progenitor cells13. In addition, 12 variants indicated a moderate effect. Recently, Bauwens et al. found that two non-coding deep-intronic variants, c.768+3223C>T and c.2919–383C>T, caused significant downregulation in their in vitro reporter studies14.
Further, the transcription factors AIRS (-762 from the position of the putative transcription initiation site), AP-1/Nrl-like (-708), Mash (-655), Ret-4 (-489), RAR/RXR (-269), and CRX/Ta (-33) were predicted to bind to the ABCA4 promoter by computational analysis using the Transfac database. In particular, the -762, -708, and -655 regions are hypothesized to have an important effect on retina function as they correspond to the region responsible for retina-specific adjustment18. Although this study highlighted the clinical importance of the ABCA4 proximal promoter, no functional studies of its genetic variants have been reported. Recently, human eye-specific cis-regulatory elements (CREs) were identified and functionally characterized using a comprehensive analysis of tissue-specific CREs, transcription factor binding, and gene expression in the retina, macula, and retinal pigment epithelium/choroid19. This study revealed that the interaction between tissue-specific CREs and transcription factors is important for the expression of genes such as ABCA4.
Stargardt disease is an autosomal recessive disease caused by ABCA4 variants (STGD1)3. Recently, Kim et al. found several ABCA4 variants in six Korean patients with Stargardt disease using targeted exome sequencing20. This study examined the effect of ABCA4 variants on ABCA4 expression. In addition, functional characterization of the genetic variants of the ABCA4 proximal promoter region determined the mechanism by which these ABCA4 variants alter promoter activity.
Results
Effects of ABCA4 variants on its expression
In a previous study, five missense variants—p.Arg290Gln, p.Asp645Asn, p.Thr1117Ala, p.Cys1140Trp, and p.Asn1588Tyr—in six Korean patients with Stargardt disease were identified through genetic analysis20. In the present study, we constructed vectors containing a wild-type ABCA4 gene and its variants and investigated ABCA4 expression levels of the variants on the plasma membrane using cell surface biotinylation assays and immunofluorescence. We observed that four of five variants had significantly decreased ABCA4 expression on the plasma membrane, whereas the expression of p.Asp645Asn was comparable with that of the wild-type (Fig. 1). In particular, the ABCA4 expression of p.Thr1117Ala, p.Cys1140Trp, and p.Asn1588Tyr was remarkably decreased by 70.9%, 40.6%, and 87.9%, respectively, compared with that of the wild-type. Further, ABCA4 expression of p.Arg290Gln was decreased by 28.4%. Proteins with trafficking defects typically undergo intracellular degradation by proteasomes or lysosomes. The ABCA4 expression of p.Arg290Gln, p.Thr1117Ala, p.Cys1140Trp, and p.Asn1588Tyr recovered to 109.8%, 72.5%, 91.2%, and 95.0%, respectively, of naïve wild-type ABCA4 expression, after treatment with the proteasomal proteolysis inhibitor MG132 (Fig. 2a). In addition, the ABCA4 expression of these variants recovered to 100.5%, 88.9%, 108.1%, and 100.9%, respectively, of naïve wild-type ABCA4 expression, after treatment with the lysosomal degradation inhibitor bafilomycin A1 (Fig. 2b). Our data suggest that p.Arg290Gln, p.Thr1117Ala, p.Cys1140Trp, and p.Asn1588Tyr are susceptible to intracellular degradation and that the decreased ABCA4 expression of these variants can be a result of proteasomal or lysosomal degradation. We also confirmed the ABCA4 expression on the plasma membrane of cells expressing each variant using immunofluorescence and observed that the ABCA4 expression of three variants, p.Thr1117Ala, p.Cys1140Trp, and p.Asn1588Tyr on the plasma membrane was markedly decreased (Fig. 3). In the case of p.Arg290Gln, although ABCA4 expression on the plasma membrane was less decreased than that of the three variants, a large faction of ABCA4 was present in the endoplasmic reticulum.
Frequency of ABCA4 promoter variants
Three common single nucleotide polymorphisms (SNPs) (minor allele frequency ≥ 5%)—c.-1086A>C (rs2151846), c.-900A>T (rs3789452) and c.-761C>A (rs3761906)—in the ABCA4 proximal promoter region were identified using SNP data from the database of single nucleotide polymorphisms (dbSNP) of the National Center for Biotechnology Information (NCBI) (https://www.ncbi.nlm.nih.gov/snp/). Using the rs number of each variant, we obtained the frequencies of these variants from the 1,000 Genomes Project (phase 3) (https://www.ensembl.org/) in four different ethnic groups: 661 Africans, 347 Americans, 504 East Asians, and 503 Europeans (Table 1). The frequencies of each minor allele in Koreans are similar to those of East Asians, except that the minor allele of the c.-1086A>C variant is C in all four ethnic groups, but A is the minor allele in Koreans [data obtained from 1,465 Koreans from the Korean Reference Genome (KRG) Database, http://152.99.75.168:9090/KRGDB/]. In addition, four haplotypes were assembled (Table 2). Haplotype 4 (H4) was used as the wild-type in this study according to the ABCA4 mRNA sequence (GenBank accession number; NM_000350.3). In addition, H1 consisted of a c.-761C>A variant, whereas H2 and H3 were composed of c.-1086A>C and c.-900A>T and c.-1086A>C, respectively (Table 2).
Effects of ABCA4 variants on promoter activity
H1 and H3 haplotypes indicated significantly altered luciferase activities compared with that of the H4 wild-type (P < 0.01 and 0.001, respectively); H1 had 22.8% increased luciferase activity, while H3 had 37.0% decreased luciferase activity (Fig. 4). The luciferase activity of H2 was comparable with that of the wild-type. In addition, the variant in H2, c.-900A>T, indicated a 27.0% increase in luciferase activity compared with that of the wild-type (Fig. 4).
Transcription factors involved in regulating ABCA4 promoter activity
ConSite (http://consite.genereg.net/cgi-bin/consite) and MatInspector (Genomatrix Software GmbH, Munich, Germany) was used to predict transcription factors binding the ABCA4 promoter near the region harboring the three variants: c.-1086A>C, c.-900A>T, and c.-761C>A. Further, GATA binding protein 2 (GATA-2) and hepatic leukemia factor (HLF) were predicted to bind to the ABCA4 promoter region and exhibited a large difference in their binding affinity between the wild-type and variant sequences. This was validated using gel shift assays with unlabeled GATA-2 or HLF consensus oligonucleotides and antibodies against GATA-2 or HLF. GATA-2 more strongly bound to the wild-type ABCA4 promoter with c.-1086A, by 2.22-fold (SD = 0.36), than the one with c.-1086C variant (lanes 4 and 7, Fig. 5a). HLF bound to the ABCA4 promoter region near the c.-900A>T variant and more strongly bound to the c.-900T variant, by 1.92-fold (SD = 0.52) than to the c.-900A wild-type (lanes 4 and 7, Fig. 5b). Additionally, GATA-2 bound to the ABCA4 promoter region near the c.-761C>A variant and more strongly bound to the c.-761A variant, by 1.67-fold (SD = 0.23), than to the c.-761C wild-type (lanes 4 and 7, Fig. 5c).
Effects of GATA-2 or HLF on ABCA4 promoter activity
The effect of GATA-2 or HLF transcription factors on ABCA4 promoter activity was examined by measuring luciferase activity after co-transfection of wild-type or variant ABCA4 promoter vectors and each transcription factor into HCT-116 cells. Both transcription factors increased ABCA4 luciferase activity in a dose-dependent manner (Fig. 6). These results suggest that GATA-2 and HLF function as gene activators of ABCA4 transcription.
Discussion
This study examined the effect of p.Arg290Gln, p.Asp645Asn, p.Thr1117Ala, p.Cys1140Trp, and p.Asn1588Tyr missense variants on ABCA4 expression. These variants were found in six Korean patients with Stargardt disease, and three of them (p.Arg290Gln, p.Thr1117Ala, and p.Asn1588Tyr) were novel in a previous study20. The p.Asp645Asn and p.Cys1140Trp variants were previously found in Korean or Chinese patients with Stargardt disease21,22. Our study indicated that the significantly decreased ABCA4 expression of p.Arg290Gln, p.Thr1117Ala, p.Cys1140Trp, and p.Asn1588Tyr variants on the plasma membrane could be due to intracellular degradation. In particular, p.Thr1117Ala, p.Cys1140Trp, and p.Asn1588Tyr indicated remarkably decreased ABCA4 expression, whereas ABCA4 expression of p.Asp645Asn was comparable with that of the wild-type. In a previous study, p.Asp645Asn indicated an increased affinity for ATP compared with that of the wild-type in ATP-labeling experiments23. Additional functional experiments including ATPase activity assays and molecular mechanism experiments are required to determine the effect of this variant on ABCA4 functions. Recently, Runhart et al. reported that a mild variant of ABCA4, p.Asn1868Ile, had incomplete penetrance and could result in late-onset Stargardt disease when it presents in trans with other severe ABCA4 variants24,25. Therefore, even if p.Asp645Asn is insufficient to cause loss-of-function of ABCA4, it can cause a disease phenotype when it is associated with another severe ABCA4 variant. In previous studies, all Korean patients with Stargardt disease were heterozygotes for two ABCA4 variants20,26. The patient with p.Asp645Asn had another variant, p.Lys2049ArgfsTer12. Genetic testing of the parents of this patient was not performed. However, the family tree indicated that the parents were not affected by the disease, and the patient did not have any other ABCA4 variant other than the two variants. In addition, p.Lys2049ArgfsTer12 was present with the p.Thr1117Ala variant in another Stargardt disease patient. In this family, the patient's parents were not affected by the disease as well, and the patient did not have any other ABCA4 variant other than the two variants26. Further, p.Lys2049ArgfsTer12 was reported in two Korean patients with Stargardt disease in another study21. Based on these findings, it can be inferred that p.Lys2049ArgfsTer12 exists in trans with p.Asp645Asn in a patient with Stargardt disease. In a previous in silico analysis, p.Lys2049ArgfsTer12 was categorized as a severe variant27.
Recently, p.Arg290Gln and p.Asn1588Tyr were categorized as mild/moderate variants whereas p.Cys1140Trp was categorized as a causative variant of unknown severity using in silico analysis27. In previous studies, patients carrying the p.Arg290Gln or p.Asn1588Tyr variants had another ABCA4 variant, p.Leu1157Ter. In another patient, the p.Cys1140Trp variant existed in trans with an in-frame ABCA4 variant, p.Ile1114del26. To date, the severity of these two variants, p.Leu1157Ter and p.Ile1114del, has not been reported. In a previous study, the researchers investigated a genotype–phenotype correlation in their patients26. They observed that patients with p.Asp645Asn, p.Thr1117Ala, p.Cys1140Trp, or p.Asn1588Tyr variant indicated typical features of Stargardt disease, flecks, bilateral macular atrophy, and blocked fluorescence in fluorescein angiography. The patient with p.Arg290Gln exhibited bull’s-eye maculopathy without flecks. The age of onset was 11–16 years, and the median best-corrected visual acuity was 20/320. To determine whether the ABCA4 variants examined in this study have a significant effect on the phenotype of Stargardt disease, analyzing the phenotype according to the genotype, with a larger number of patients, is necessary.
Allikmets et al. reported several putative important sites in the ABCA4 promoter using the Transfac transcription factor database18. Although photoreceptor-specific elements were not identified in the ABCA4 promoter region, similar sequences were found in the regulatory regions of other photoreceptor genes including rhodopsin and S-antigen/arrestin. However, the functional roles of these sites were not examined using molecular experimental tools. Recently, Cherry et al. identified and functionally characterized human eye-specific CREs19. In their study, a promoter variant (rs11802887) and an enhancer variant (rs752024867) found in patients with Stargardt disease indicated significantly increased or decreased reporter activity, respectively, although both were not within the readily recognizable transcription factor-binding motif.
This study investigated the effect of genetic variants in the ABCA4 proximal promoter on ABCA4 transcription using in vitro assays. The luciferase reporter assay indicated that c.-1086A>C, c.-900A>T, and c.-761C>A variants had significantly altered luciferase activities compared with that of the wild-type. We found that GATA-2 was bound to the ABCA4 promoter region near the c.-1086A>C or c.-761C>A variant site. GATA-2 plays an important role in the development of various tissue types. The GATA family is originally divided into the hematopoietic- (GATA-1/2/3) or cardiac (GATA-4/5/6) family of transcription factors and several variants in GATA2 are associated with various blood diseases28,29,30,31,32. Further, GATA-2 plays an important role in other tissues, including retina, central nervous system, and prostate33,34,35. In particular, a previous study revealed that GATA-2 is an essential transcription factor for the transcription of neuroglobin, which is mainly expressed in the retina and brain35. Regarding the effect of GATA-2 on the regulation of transporters, GATA-2 plays an important role in maintaining water homeostasis in the body by controlling aquaporin 2 expression in the collecting tubules36. This study found that the sequence of wild-type c.-1086A (ACTATCTCT) is similar to the consensus sequence (WGATAR) of GATA-2. Our prediction that the c.-1086C variant (ACTCTCTCT sequence) reduces GATA-2 binding affinity, because it is less consistent with the GATA-2 consensus sequence, was confirmed using a gel shift assay. The c.-761A variant also had a sequence similar to the consensus sequence of GATA-2, GGGATGGAA. The wild-type c.-761C contains GGGCTGGAA, which is hypothesized to lower the binding affinity of GATA-2, and this was confirmed using a gel shift assay. In addition, we observed that GATA-2 acts as an activator of the ABCA4 promoter, similar to the role in the transcription of neuroglobin. Our data suggest that the decreased luciferase activity of c.-1086A>C results from the reduced binding of GATA-2, while the increased luciferase activity of c.-761C>A results from the increased binding of GATA-2.
HLF (originally known as E2A-HLF) in childhood acute lymphocytic leukemia is a chimeric transcription factor produced by the translocation of E2A on chromosome 19 and HLF on chromosome 1737. Although the t (19:17) E2A-HLF leukemia subtype is rare, it has a high mortality rate because it is resistant to chemotherapy38. HLF is mainly expressed in the liver, lungs, kidneys, and neurons, but not in normal blood cells39. The role of HLF in the body is not clearly elucidated although it is involved in activating coagulation factor VII and factor IX genes and in synapse formation in the central nervous system in a mouse model39,40. In a previous study, we revealed that HLF binds to the promoter region of lactosylceramide α-2,3-sialytransferase 5 (ST3GalV) and regulates the transcription of this gene41. ST3GalV is an enzyme involved in the production of ganglioside in the body. It is distributed throughout the body and is particularly highly expressed in the central nervous system42,43. In this study, we observed that the sequence of the c.-900T variant (GATAACACA) was similar to the consensus sequence of HLF (RTTACRYAAT). In addition, it was predicted that the binding affinity for HLF is weaker in the wild-type c.-900A because the wild-type sequence (GAGAACACA) is not as similar to the consensus sequence of HLF; this prediction was confirmed using a gel shift assay. Furthermore, HLF activated the ABCA4 promoter. These results suggest that the increased luciferase activity of c.-900A>T is a consequence of the stronger binding between the c.-900T variant and HLF.
This study revealed that several ABCA4 variants found in patients with Stargardt disease could affect ABCA4 expression, and common variants of the ABCA4 proximal promoter alter the ABCA4 transcriptional activity, which is regulated by GATA-2 and HLF. In particular, the H3 haplotype reduced promoter activity; therefore, investigating whether this haplotype is associated with the ABCA4-associated retinopathy, including Stargardt disease, through presenting with other ABCA4 variants, is necessary.
Methods
Plasmid construction
A reporter plasmid containing the ABCA4 wild-type promoter sequences (− 1,116 to + 50 bp from the translational start site of ABCA4) was amplified and inserted into the pGL4.11b[luc2] vector (Promega Corporation, Madison, WI, USA). A plasmid containing the wild-type ABCA4 cDNA (Horizon Discovery, Cambridge, UK) was subcloned into the p3XFLAG-CMV vector. Variant-bearing plasmids were generated using the QuikChange® II site-directed mutagenesis kit (Agilent Technologies, Santa Clara, CA, USA). Primers used for the construction of a reporter plasmid or variant-bearing plasmids are listed in Supplementary Table 1. All the DNA sequences were confirmed using direct sequencing.
Surface biotinylation assay
After transfection of the ABCA4 wild-type or variant-bearing plasmids into HEK-293T (human embryonic kidney) cells using Lipofectamine LTX and Plus reagents (Thermo Fisher Scientific, Waltham, MA, USA), biotinylation assays were conducted using a cell surface protein isolation kit (Thermo Fisher Scientific) according to the manufacturer's protocol. Protein samples from biotinylation assays were subjected to immunoblotting. Rabbit polyclonal anti-Na+/K+ ATPase α-1 antibody (Merck, Kenilworth, NJ, USA) was used as the internal standard. The signal was acquired using an Amersham ImageQuant 800 biomolecular imager (Cytiva, Marlborough, MA, USA) and the intensity of each band was measured using ImageJ software (National Institute of Health, Bethesda, MD, USA).
Immunoblotting
Immunoblotting was performed using mouse anti-FLAG M2 primary antibody (Merck) or goat anti-β-actin antibody (Santa Cruz Biotechnology, Dallas, TX, USA) and the corresponding secondary antibodies. Fifteen micrograms of protein was loaded on mini-protein TGX gels (Bio-Rad, Hercules, California, USA) and transferred using a trans-blot turbo RTA transfer kit and trans-blot turbo transfer system (Bio-Rad). Cells were treated with 10 µM MG132 (Sigma-Aldrich, Burlington, MA, USA) or 10 nM bafilomycin A1 (MedChemExpress, Monmouth Junction, NJ, USA) 24 h after transfection to examine their effects on ABCA4 variants. Membranes were developed with ECL detection reagents (Thermo Fisher Scientific). The signal was acquired using an Amersham ImageQuant 800 biomolecular imager and the intensity of each band was measured using ImageJ software.
Immunofluorescence
HEK-293T cells were seeded into 4-well chamber slides (Thermo Fisher Scientific) and the ABCA4 wild-type or variant-bearing plasmids were transfected into those cells. After transfection, the cells were fixed and permeabilized with 100% methanol (prechilled at − 20 °C) at room temperature for 5 min and blocked with 1% bovine serum albumin for 30 min. To examine the intracellular localization of ABCA4, cells were incubated with anti-FLAG M2, anti-BiP (Abcam, Waltham, MA, USA), or anti-giantin (Abcam) antibodies. The cells were then washed thrice with phosphate-buffered saline, and incubated with Alexa Fluor® 488 rabbit anti-mouse IgG or Alexa Fluor® 594 goat anti-rabbit IgG (Life Technologies) secondary antibodies. Nucleic acids were stained with DAPI (4’,6-diamidino-2-phenylindole, Vector Laboratories, Burlingame, CA, USA). Images were obtained using a confocal laser scanning microscope and analyzed using an LSM image examiner (Carl Zeiss, Oberkochen, Germany).
Genetic analysis of the ABCA4 proximal promoter
To identify common SNPs in the proximal region of ABCA4 promoter, SNP data were used from the dbSNP of the NCBI. Next, the frequency data from the 1,000 Genomes Project (phase 3) in four different ethnic groups—661 Africans, 347 Americans, 504 East Asians, and 503 Europeans—were used to identify the frequencies of these variants. The frequencies of the minor alleles in each variant in Koreans were obtained from the KRG database. The haplotype frequencies were determined using Haploview software version 4.3 (Broad Institute, Cambridge, MA, USA). Nucleotide location numbers were assigned from the translational start site based on the ABCA4 mRNA sequence (GenBank accession number NM_000350.3).
Promoter activity
GATA-2 cDNA or HLF cDNA (Horizon Discovery) was subcloned into the pcDNA3.1 ( +) vector (Life Technologies, Carlsbad, CA, USA). Varying amounts of GATA-2 or HLF plasmids were co-transfected with the ABCA4 reporter plasmid (wild-type or variants) into HCT-116 (human colon carcinoma) cells using Lipofectamine LTX and Plus reagents. After transfection, luciferase activity was measured using the Dual Luciferase® Reporter Assay System (Promega Corporation) according to the manufacturer’s protocol and quantified using a luminometer (Promega Corporation).
Gel shift assay
Gel shift assays were performed as previously described44. In this study, 10–20 μg of a nuclear extract from HCT-116 cells was incubated with 32P-labeled (1 × 105 or 2 × 105 counts/min) oligonucleotides. Each sample was then subjected to electrophoresis for 90–150 min at 80 V, and the CP-BU film was exposed to the dried gel (Agfa, Mortsel, Belgium) at − 80 °C for 16 h. Competition assays involved adding 100-fold molar excess of unlabeled GATA-2 or HLF consensus oligonucleotides prior to the binding reaction. Antibodies (3–6 µg) against GATA-2 (Santa Cruz Biotechnology) or HLF (Merck) were used for the supershift assay. Band intensities were measured using ImageJ software. Oligonucleotides used in the gel shift assays are listed in Supplementary Table 1.
Statistical analyses
Statistical analyses were performed using GraphPad Prism 8.0 (GraphPad Software Inc., San Diego, CA, USA). P values of the results obtained before- and after MG132 or bafilomycin A1 treatment were calculated using Student’s t test for comparison. Other P values were calculated using one-way analysis of variance, followed by Dunnett’s two-tailed test. P < 0.05 was considered statistically significant.
Data availability
All data generated or analyzed during the current study are included in this article (and its supplementary information files).
References
Allikmets, R. A photoreceptor cell-specific ATP-binding transporter gene (ABCR) is mutated in recessive stargardt macular dystrophy. Nat. Genet. 17, 122 (1997).
Illing, M., Molday, L. L. & Molday, R. S. The 220-kDa rim protein of retinal rod outer segments is a member of the ABC transporter superfamily. J. Biol. Chem. 272, 10303–10310 (1997).
Molday, R. S., Garces, F. A., Scortecci, J. F. & Molday, L. L. Structure and function of ABCA4 and its role in the visual cycle and Stargardt macular degeneration. Prog. Retin. Eye Res. 89, 101036 (2022).
Quazi, F., Lenevich, S. & Molday, R. S. ABCA4 is an N-retinylidene-phosphatidylethanolamine and phosphatidylethanolamine importer. Nat. Commun. 3, 925 (2012).
Tsybovsky, Y., Molday, R. S. & Palczewski, K. The ATP-binding cassette transporter ABCA4: Structural and functional properties and role in retinal disease. Adv. Exp. Med. Biol. 703, 105–125 (2010).
Hamel, C. P. Cone rod dystrophies. Orph. J. Rare Dis. 2, 7 (2007).
Jiang, F. et al. Screening of ABCA4 gene in a Chinese cohort with stargardt disease or cone-rod dystrophy with a report on 85 novel mutations. Invest Ophthalmol. Vis. Sci. 57, 145–152 (2016).
Makelainen, S. et al. An ABCA4 loss-of-function mutation causes a canine form of Stargardt disease. PLoS Genet. 15, e1007873 (2019).
Martinez-Mir, A. et al. Retinitis pigmentosa caused by a homozygous mutation in the stargardt disease gene ABCR. Nat. Genet. 18, 11–12 (1998).
Nassisi, M. et al. Expanding the mutation spectrum in ABCA4: Sixty novel disease causing variants and their associated phenotype in a large French stargardt cohort. Int. J. Mol. Sci. 19, 2196 (2018).
Schulz, H. L. et al. Mutation spectrum of the ABCA4 gene in 335 stargardt disease patients from a multicenter german cohort-impact of selected deep intronic variants and common SNPs. Invest Ophthalmol. Vis. Sci. 58, 394–403 (2017).
Smaragda, K. et al. Mutation spectrum of the ABCA4 gene in a greek cohort with stargardt disease: Identification of novel mutations and evidence of three prevalent mutated alleles. J. Ophthalmol. 2018, 5706142 (2018).
Cremers, F. P. M., Lee, W., Collin, R. W. J. & Allikmets, R. Clinical spectrum, genetic complexity and therapeutic approaches for retinal disease caused by ABCA4 mutations. Prog. Retin Eye Res. 79, 100861 (2020).
Bauwens, M. et al. ABCA4-associated disease as a model for missing heritability in autosomal recessive disorders: Novel noncoding splice, cis-regulatory, structural, and recurrent hypomorphic variants. Genet Med. 21, 1761–1771 (2019).
Fadaie, Z. et al. Identification of splice defects due to noncanonical splice site or deep-intronic variants in ABCA4. Hum. Mutat. 40, 2365–2376 (2019).
Khan, M. et al. Resolving the dark matter of ABCA4 for 1054 Stargardt disease probands through integrated genomics and transcriptomics. Genet Med. 22, 1235–1246 (2020).
Khan, M. et al. Cost-effective molecular inversion probe-based ABCA4 sequencing reveals deep-intronic variants in stargardt disease. Hum. Mutat. 40, 1749–1759 (2019).
Allikmets, R. et al. Organization of the ABCR gene: Analysis of promoter and splice junction sequences. Gene 215, 111–122 (1998).
Cherry, T. J. et al. Mapping the cis-regulatory architecture of the human retina reveals noncoding genetic variation in disease. Proc. Natl. Acad. Sci. U. S. A. 117, 9001–9012 (2020).
Kim, M. S. et al. Genetic mutation profiles in Korean patients with inherited retinal diseases. J. Korean Med. Sci. 34, e161 (2019).
Sung, Y., Choi, S. W., Shim, S. H. & Song, W. K. Clinical and genetic characteristics analysis of Korean patients with stargardt disease using targeted exome sequencing. Ophthalmologica 241, 38–48 (2019).
Zhang, X. et al. Molecular diagnosis of putative Stargardt disease by capture next generation sequencing. PLoS ONE 9, e95528 (2014).
Shroyer, N. F., Lewis, R. A., Yatsenko, A. N., Wensel, T. G. & Lupski, J. R. Cosegregation and functional analysis of mutant ABCR (ABCA4) alleles in families that manifest both stargardt disease and age-related macular degeneration. Hum. Mol. Genet. 10, 2671–2678 (2001).
Runhart, E. H. et al. The common ABCA4 variant p.Asn1868Ile shows nonpenetrance and variable expression of stargardt disease when present in trans with severe variants. Invest Ophthalmol. Vis. Sci. 59, 3220–3231 (2018).
Runhart, E. H. et al. Association of sex with frequent and mild ABCA4 alleles in stargardt disease. JAMA Ophthalmol. 138, 1035–1042 (2020).
Joo, K., Seong, M. W., Park, K. H., Park, S. S. & Woo, S. J. Genotypic profile and phenotype correlations of ABCA4-associated retinopathy in Koreans. Mol. Vis. 25, 679–690 (2019).
Cornelis, S. S. et al. Personalized genetic counseling for Stargardt disease: Offspring risk estimates based on variant severity. Am. J. Hum. Genet. 109, 498–507 (2022).
Dickinson, R. E. et al. Exome sequencing identifies GATA-2 mutation as the cause of dendritic cell, monocyte, B and NK lymphoid deficiency. Blood 118, 2656–2658 (2011).
Hsu, A. P. et al. Mutations in GATA2 are associated with the autosomal dominant and sporadic monocytopenia and mycobacterial infection (MonoMAC) syndrome. Blood 118, 2653–2655 (2011).
Kazenwadel, J. et al. Loss-of-function germline GATA2 mutations in patients with MDS/AML or MonoMAC syndrome and primary lymphedema reveal a key role for GATA2 in the lymphatic vasculature. Blood 119, 1283–1291 (2012).
Pasquet, M. et al. High frequency of GATA2 mutations in patients with mild chronic neutropenia evolving to MonoMac syndrome, myelodysplasia, and acute myeloid leukemia. Blood 121, 822–829 (2013).
Tremblay, M., Sanchez-Ferras, O. & Bouchard, M. GATA transcription factors in development and disease. Development 145, dev164384 (2018).
Lahti, L. et al. Differentiation and molecular heterogeneity of inhibitory and excitatory neurons associated with midbrain dopaminergic nuclei. Development 143, 516–529 (2016).
Xiao, L. et al. The essential role of GATA transcription factors in adult murine prostate. Oncotarget 7, 47891–47903 (2016).
Tam, K. T. et al. Identification of a novel distal regulatory element of the human neuroglobin gene by the chromosome conformation capture approach. Nucleic Acids Res. 45, 115–126 (2017).
Yu, L. et al. GATA2 regulates body water homeostasis through maintaining aquaporin 2 expression in renal collecting ducts. Mol. Cell. Biol. 34, 1929–1941 (2014).
Inaba, T. et al. Fusion of the leucine zipper gene HLF to the E2A gene in human acute B-lineage leukemia. Science 257, 531–534 (1992).
Inukai, T. et al. Hypercalcemia in childhood acute lymphoblastic leukemia: Frequent implication of parathyroid hormone-related peptide and E2A-HLF from translocation 17;19. Leukemia 21, 288–296 (2007).
Hitzler, J. K. et al. Expression patterns of the hepatic leukemia factor gene in the nervous system of developing and adult mice. Brain Res. 820, 1–11 (1999).
Begbie, M., Mueller, C. & Lillicrap, D. Enhanced binding of HLF/DBP heterodimers represents one mechanism of PAR protein transactivation of the factor VIII and factor IX genes. DNA Cell Biol. 18, 165–173 (1999).
Park, H. J. et al. Identification and functional characterization of ST3GAL5 and ST8SIA1 variants in patients with thyroid-associated ophthalmopathy. Yonsei Med. J. 58, 1160–1169 (2017).
Tsuji, S. Molecular cloning and functional analysis of sialyltransferases. J. Biochem. 120, 1–13 (1996).
Proia, R. L. Gangliosides help stabilize the brain. Nat Genet. 36, 1147–1148 (2004).
Park, H. J. et al. Identification of OCTN2 variants and their association with phenotypes of Crohn’s disease in a Korean population. Sci. Rep. 6, 22887 (2016).
Acknowledgements
This work was supported by the National Research Foundation of Korea grants funded by the Korean government (MSIT) (2020R1A5A2019210 and 2015R1D1A1A01056652).
Author information
Authors and Affiliations
Contributions
J.H.C. designed the study. B.M.K., H.S.S., J.Y.K., E.Y.K., S.Y.H., M.K., and J.H.C. carried out the experiments and analyzed the data. J.H.C. wrote the manuscript. All the authors reviewed the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Kim, B.M., Song, H.S., Kim, JY. et al. Functional characterization of ABCA4 genetic variants related to Stargardt disease. Sci Rep 12, 22282 (2022). https://doi.org/10.1038/s41598-022-26912-6
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-022-26912-6
- Springer Nature Limited