Stargardt macular dystrophy and therapeutic approaches

Stargardt macular dystrophy (Stargardt disease; STGD1; OMIM 248200) is the most prevalent inherited macular dystrophy. STGD1 is an autosomal recessive disorder caused by multiple pathogenic sequence variants in the large ABCA4 gene (OMIM 601691). Major advances in understanding both the clinical and molecular features, as well as the underlying pathophysiology, have culminated in many completed, ongoing and planned human clinical trials of novel therapies. The aims of this concise review are to describe (1) the detailed phenotypic and genotypic characteristics of the disease, multimodal imaging findings, natural history of the disease, and pathogenesis, (2) the multiple avenues of research and therapeutic intervention, including pharmacological, cellular therapies and diverse types of genetic therapies that have either been investigated or are under investigation and (3) the exciting novel therapeutic approaches on the translational horizon that aim to treat STGD1 by replacing the entire 6.8 kb ABCA4 open reading frame.


INTRODUCTION
2][3][4][5][6][7][8] STGD1 was first described by Karl Stargardt in 1909 and is characterised by bilateral progressive loss of visual acuity (VA) and central vision. 9There are three presentations of STGD1, childhood onset, adulthood onset and late onset, with earlier presentation being associated with a worse prognosis. 3 7 10-20TGD1 typically presents with a variable degree of macular atrophy and yellow-white flecks at the level of the retinal pigment epithelium (RPE) (figure 1). 8 10 11 14 21However, there are a broad range of manifestations resulting in a large spectrum of clinical presentations, onset, progression, psychophysical and electrophysiological findings, as well as variable prognosis. 6 10-13 15-20 22-32he global prevalence of STGD1 has been estimated at 1 per 6578. 33Due to the progressive nature and often early onset of STGD1, patients typically face long-term health-related financial, emotional and psychological implications.Although information on the economic burden of STGD1 alone is not available, these impacts have been studied in a broad range of inherited retinal diseases (IRDs). 34Some studies estimate the total cost is over US$27.5 billion per year among people aged 40 years and younger with eye disorders. 35 36n 1997, disease-causing sequence variants in the ABCA4 (ATP binding cassette subfamily A member 4; OMIM: 601691) gene were identified as the cause of STGD1 37 ; with more than 2000 variants found to date.The carrier frequency for a disease-causing variant in ABCA4 may be as high as 1:20; although the true prevalence of retinopathy attributed to ABCA4 variants is likely much higher than that of STGD1, given it can also cause other phenotypes including cone dystrophy, cone-rod dystrophy and rod-cone dystrophy. 1 3 6 7 22 38Moreover, the bone spicule pigmentation of ABCA4associated retinopathy attributed to severe cone-rod dystrophy (formerly retinitis pigmentosa inversa) is now widely accepted as a sign of late-stage cone-rod dystrophy and peripheral degeneration, rather than rod-cone dystrophy. 39n increasing amount of research on the clinical and molecular genetics of STGD1/ABCA4 has been performed over the past 15 years.This has facilitated a growing understanding of the underlying pathophysiology, which has resulted in both completed and ongoing trials, as well as a broad range of planned clinical trials. 6 7 40-42 Increasingly, precision medicine focusing on particular variants and mechanisms has been gaining attention (including gene editing). 7 42 47he aim of this review is to describe the phenotypic and genotypic characteristics, imaging findings, natural history and pathogenesis of the disease.Additionally, the characteristics of particular ABCA4 variants, a pathogenicity assessment and a concise overview of the therapeutic landscape-past, present and future-will be presented.

DISEASE OVERVIEW Gene family/gene function
The ABCA4 gene is a large, highly polymorphic gene with an estimated size of 6819 bp encoding a 2,273amino acid protein, including 50 exons. 37ABCA4, formerly described as ABCR, is a member of the ABC transporter gene superfamily, encoding the retinalspecific transmembrane protein, a member of the ATP-binding cassette transporter superfamily. 3 6 48BCA4 contains two transmembrane domains, two Review glycosylated extracellular domains and two nucleotide-binding domains (figure 2A). 3 6 48 ABCA4 is localised along the rim of the rod/cone outer segment discs and is involved in the active transport of retinoids from photoreceptor to RPE in the retinoid cycle.[48][49][50][51] The visual/ retinoid cycle involves a series of enzyme-catalysed reactions that convert all-trans retinal, generated with photobleaching of rhodopsin/cone opsin, back to 11-cis retinal.48 50-53 All-trans retinal is released from the light-activated rhodopsin/cone opsin into the rod/cone outer segments to form a complex with phosphatidylethanolamine (PE), resulting in N-retinylidene-PE (N-ret-PE).6 48 54 This complex is then actively transported to the disc surface by ABCA4 (figure 2B,C). ABCA4 s also been shown to be expressed at lower levels in the RPE, where it may serve a similar function for the recycling of retinaldehydes.54

Molecular genetics
The vast allelic heterogeneity of ABCA4 is clearly demonstrated by the number of reported sequence variations (>2000) to date, resulting in macular dystrophy, cone dystrophy, cone-rod and rod-cone dystrophy. 3 6-8Due to this heterogeneity, establishing genotype-phenotype correlations is highly challenging.Likewise, the identification of ABCA4 genetic characteristics related to intronic variants remains largely elusive, despite genetic sequencing advances.6][57] However, due to the highly polymorphic nature of the ABCA4 gene, the genetic and pathogenic features of deep intronic variants remain difficult to characterise.
Null variants or variants predicted to be more deleterious are generally associated with earlier onset disease and characterised by a more severe, rapidly progressive phenotype, often with more generalised retinal involvement. 6 8 11-13 16 25 26 32ilder variants, such as missense variants, are often associated with later onset disease, typically milder, more slowly progressive and more likely isolated to the macula. 58Although certain missense variants can produce severe functional effects similar to nulls (eg, p.Leu541Pro/p.Ala1038Val (complex), p.Glu1022Lys, p.Cys1490Tyr, p.Glu1087Lys, p.Thr1526Met, p.Arg1640Trp and p.Cys2150Tye p.Cys2150Tyr). 13 16 25 26 58The interaction between the variants (including disease-causing and benign variants) may also affect function. 59Nevertheless, certain missense variants, including p.Arg2030Gln, are commonly observed in the mildest ABCA4-associated phenotype, late-onset/foveal sparing STGD1 (FS-STGD1). 14 26hile ABCA4 allelic heterogeneity is high, there are founder variants associated with STGD1 in various racial and ethnic groups as well as differences in clinical features related to ABCA4-retinopathy. 6There have been larger cohort STGD1 studies featuring the genotypic profile and phenotypic correlations for the White populations in European/North American, although there are a limited number of studies for the Latin, Asian, African and other populations. 5 8 32 60 61However, further studies are required to better understand the clinical difference and effects across different ethnic and racial groups.
A category of rare hypomorphic alleles has also been characterised, which are typically observed in milder phenotypes with better prognosis. 62Lee et al showed that these hypomorphic variants can modulate the severity of the phenotype irrespective of the severity of the allele in trans. 62Notably, the mechanism of hypomorphic alleles or milder variants has been attributed to either reduced function of the ABCA4 protein produced in normal amounts (ie, missense variants) or reduced production of a normal functioning protein (ie, splice variants).The aberrant splicing in the ABCA4 gene and resulting variants, whose pathogenicity was previously unknown, has more recently been reclassified as pathogenic based on midi-gene and fibroblast assays. 63 64

Molecular mechanisms
Failure of transport due to ABCA4 dysfunction or mislocalisation leads to the inefficient removal of N-ret-PE from photoreceptor outer segments, resulting in an accumulation of bisretinoid compounds in the outer segment discs and ultimately in toxic levels of bisretinoid A2PE in photoreceptor membranes. 48 49A2PE is hydrolysed to form the highly toxic metabolite N-retinylidene-N-retinyl-ethanolamine (A2E), which accumulates as a major component of lipofuscin in RPE cells, and ultimately causes RPE dysfunction and death, with subsequent photoreceptor dysfunction/loss (figure 2D). 53revious studies of STGD1 mouse models (ie, ABCA4 knockout) support the aforementioned pathogenesis; however, there are limitations such as lack of a macula in mice and the mild phenotype in mouse models showing a later-onset disease with slower degeneration than that of typical patients with STGD1. 51 65Moreover, there is data from multimodal highresolution imaging studies in humans that in some cases photoreceptor cell loss may precede RPE cell dysfunction/loss. 17 19 20 66 67

Clinical aspects
Patients with STGD1 commonly present with progressive bilateral central vision loss.The onset is often in the first or second decades of life. 11 12 24The onset relates to the disease severity; an earlier onset disease is associated with more deleterious variants compared with adult-onset disease, which is more frequently due to missense variants. 11-14 16 25-27omprehensive investigations are crucial for clinical diagnosis and monitoring, including fundus photography, fundus autofluorescence (FAF) imaging, spectral-domain optical coherence tomography (SD-OCT) and electrophysiological assessment. 1 3 6 7 Likewise, clinical classifications are useful to assess the disease severity associated with a particular genotype group. 11 12 19 20 23 25 326][17] Retinal imaging with FAF, SD-OCT and electrophysiological assessment (including pattern, full-field and multifocal electroretinograms; PERG, FFERG, mfERG) are useful for diagnosis. 42 68-70Notably, children with STGD1 may not have retinal flecks on funduscopy or FAF at the early stage, but over time may develop these flecks associated with increasing macular atrophy. 15 16][17] Electrophysiological assessment is particularly helpful in providing better-informed advice on prognosis. 11A classification of three functional phenotypes based on electrophysiological findings is well-established: group 1-severe PERG abnormality (macular dysfunction) with normal FFERGs; group 2-severe PERG abnormality with additional generalised cone dysfunction on FFERGs and group 3-severe PERG abnormality with additional generalised cone and rod dysfunction on FFERGs. 11

Review
longitudinal ERG study has confirmed the prognostic implications of the aforementioned ERG groups, with group 1 having the best prognosis; group 2 having an intermediate or variable prognosis; and group 3 having the worst prognosis. 11All patients with initial rod ERG involvement demonstrated clinically significant electrophysiological deterioration; whereas, only 20% of patients with normal FFERGs at baseline showed clinically significant progression over time. 11STGD1 with a later age of onset has been increasingly recognised.Patients with late-onset STGD1 often develop the FS phenotype (FS-STGD1). 10 14 71FS-STGD1 thereby is characterised by relatively preserved VA and foveal structure and function in the early and intermediate stages of the disease. 14SD-OCT often exhibits outer retinal tubulation at the edge of atrophy, suggesting that the primary site of degeneration of this phenotype is the RPE and choroid. 14On the other hand, patients with foveal atrophy can manifest photoreceptor cell loss at the fovea at the early stage.Therefore, the presence of two distinct phenotypes-non-FS-STGD1, which is primarily childhood-onset and adulthood-onset STGD1, and FS-STGD1-suggests more than one disease mechanism in ABCA4-associated retinopathy. 14The fact that a different distribution of disease-causing variants exists between these two phenotypes appears to support this hypothesis. 14 26gure 2 Molecular mechanisms of STGD1 (ABCA4-retinopathy) a schematic of ABCA4 protein structure (A), the visual cycle (B), transport (C) and failure of transport leading to retinal degeneration (D).The ABCA4 gene transcribes a large retina-specific ABCA4 protein with two transmembrane domains (TMD), two glycosylated extracellular domains (ECD) and two nucleotide-binding domains (NBD) (A).All-trans retinal is released from the light-activated rhodopsin/cone opsin into the rod/cone outer segments (B) to form a complex with phosphatidylethanolamine (PE), resulting in N-ret-PE, then this complex is actively transported to the disc surface by ABCA4 (C).Failure of this transport results in accelerated deposition of a major lipofuscin fluorophore (A2E) in the RPE, which causes RPE dysfunction and cell death, with subsequent photoreceptor cell loss over time (D).

Review Natural history
Natural history studies play a key role in advancing understanding of disease progression. 20 24Over the past 8 years, multicentre, international, large-cohort studies (>250 subjects) have been conducted: the retrospective and prospective Natural History of the Progression of Atrophy Secondary to Stargardt Disease (ProgStar) studies. 24The aims were to characterise the natural history and identify sensitive, reliable and clinically relevant outcome measures, which could be employed in clinical trials. 24 27-31In a ProgStar retrospective study of a subset of 224 eyes (mean age, 33.0±15.1 years), the total mean area of definitely decreased autofluorescence (DDAF) at the first visit was 2.6 mm 2 , and the mean progression of DDAF was 0.51 mm 2 /year. 72In a prospective study with 12 months of observation, the mean area of DDAF at baseline was 3.93 mm 2 , and the estimated progression of DDAF was 0.76 mm 2 /year. 73The rate of progression was dependent on the initial size of the lesion in both studies, as previously reported by other longitudinal studies. 12 74AF imaging may serve as a monitoring tool for interventional clinical trials that aim to slow anatomical disease progression. 20 42 67Lesion size at baseline appears to be a strong predicting factor for lesion growth and can be partially accounted for by square root transformation. 12 20 42 67 75tudies using en face SD-OCT and OCT angiography (OCTA) have shown that the area of photoreceptor ellipsoid zone (EZ) loss was 1.6-fold greater than the area of RPE atrophy, which suggests that photoreceptor degeneration may precede RPE loss in STGD1. 76Moreover, OCTA showed that choriocapillaris vascular density was abnormal even beyond the areas of photoreceptor EZ and RPE loss, supporting a complex chorioretinal-RPE pathophysiology due to ABCA4 dysfunction. 76These findings may also be useful for developing end points in clinical trials.

THERAPEUTIC APPROACHES
Although there are currently no proven cures for STGD1, there are multiple treatment avenues being investigated.In addition to retinal prosthesis, 77 there are clinical trials of pharmacological agents, stem cell therapy and genetic therapies (see summary in table 1). 3 6-8 40-42 45 Pharmacological therapies are arguably the most advanced and closest to potential approval as meaningful treatments. 6 7 42

Pharmacological therapy
Several pharmacological agents have been specifically developed that target different aspects of the retinoid cycle and are potentially beneficial in slowing or preventing progression in STGD (figure 3A), with some studies also reporting improvements in retinal and/or visual function (table 1). 3 6 8 42 The aims of these agents are either (1) lowering the formation of toxic products of the retinoid cycle by reducing delivery of vitamin A or inhibition of various enzymes participating in the cycle, including drugs such as emixustat, [78][79][80] ALK-001, LBS-008, STG-001, fenretinide and A1120; or (2) directly targeting toxic metabolites such as A2E or pathways activated by these metabolites (eg, the complement cascade), including soraprazan and Avacincaptad pegol.

Cellular therapies
For the management of advanced disease, cell replacement strategies offer potential benefit.A phase 1/2 clinical trial (NCT01469832) of human embryonic stem cell (hESC)derived RPE cells for treating severe advanced STGD1 has been completed. 43 84Findings from the UK site of this trial identified subretinal hyperpigmentation consistent with the survival of viable transplanted hESC-derived RPE cells. 84Borderline improvements in VA were noted in 4 of 12 patients; however, microperimetry did not demonstrate evidence of functional benefit at 12 months. 84A phase 1 clinical trial testing the long-term safety and tolerability of hESC-derived RPE (NCT01625559) showed no adverse events, with favourable results. 85Further trials are anticipated, including evaluation of combined RPE and photoreceptor transplants, which are either derived from hESCs or induced pluripotent stem cells (iPSC).
Trials involving autologous bone marrow-derived stem cells (BMSC; NCT01920867, NCT03011541, NCT03772938) are at various stages of completion.One study (NCT01920867) showed improvement in 61.8% of the eyes treated, with 76.9% of patients exhibiting VA improvement.Other studies involving BMSC treatment (NCT03772938, NCT03011541) are still active with no results yet reported.

Genetic therapies
Gene replacement therapy has been increasingly applied to photoreceptor diseases, aiming to slow or prevent further degeneration and/or improve function in early to intermediate stage disease. 7 40-42 86Preclinical studies in gene replacement showing phenotypic improvement in abca4 −/− mice have subsequently encouraged the development of human gene therapy trials. 87 88Adeno-associated virus (AAV) vectors have been the leading choice for gene delivery in human gene therapy; however, the AAV capsids exhibit limited cargo capacity.The ABCA4 gene is far larger than the current AAV vector capacity. 87onsidering the larger cargo capacity of lentiviruses, subretinal injection of a lentiviral vector delivering ABCA4 (SAR422459) was developed.The StarGen phase I/II trial for this therapy (NCT01367444) was terminated early, with a longer-term follow-up study ongoing (NCT01736592). 89Although there were no safety concerns in either of these trials, there was no evidence of visual improvement. 46 90ptogenetics represents a genetic therapy for advanced disease, where residual non-photoreceptor cells are made light sensitive by using AAV to deliver often an opsin-related photopigment. 91This approach is being explored in a Phase II clinical trial in STGD1, with AAV2 carrying a multicharacteristic opsin gene expression cassette (NCT05417126). 92

Future treatment options
In addition to treatments currently undergoing clinical trials, there are several therapeutic approaches on the horizon for

Review
STGD1. 93Anti-sense oligonucleotide (AON) treatments have exhibited great potential for the personalised treatment of patients that carry one of the ABCA4 splice variants. 55 57Phase I/II clinical trials for the use of an AON-based therapeutic intravitreal injection to treat Leber congenital amaurosis (NCT03140969, NCT03913130), retinitis pigmentosa and Usher syndrome (NCT05085964) were conducted, but two of these studies (NCT03913130, NCT05085964) were terminated early for reasons unrelated to safety.Research involving the application of AON-based therapy has recently shown promise at preventing further deterioration in Stargardt disease models. 94ther therapeutic methods being explored include gene therapy systems that use alternative delivery vectors.As mentioned above, there are fundamental limitations to using AAVs in STGD1, principally cargo capacity, as well as concerns about immune reactions to the viral vector itself. 95 96Thus, future treatment methodologies that employ non-viral vectorssuch as cationic lipids and lipid nanoparticles (LNPs)-would be potentially safer than viral vector options with respect to the absence of immunogenic viral proteins.LNPs have also shown robust capability to condense and deliver various nucleic acid molecules up to several million nucleotides, 97 while concurrently protecting the DNA/RNA cargo from unknown chromosomal position effects. 98 99However, the level of expression and transfection efficiency for non-viral vectors is typically much lower than viral vectors.Recent strategies such as PEGylation of LNPs or use of a pH-sensitive amino lipid have been shown to markedly enhance efficiency and targeting of ocular delivery. 100  To target disordered transport due to ABCA4 dysfunction, adeno-associated virus (AAV) therapies deliver the large 6.4 kb ABCA4 gene (>4.7 kb AAV cargo limit) to the nucleus by splicing together fragments of the ABCA4 gene, wherein the transgene remains in an episomal state.Gene editing therapies cut or alter single nucleotide(s) within the ABCA4 gene via techniques such as CRISPR-Cas, which targets specific variants.Gene coding replaces the entire ABCA4 gene via an engineered transposase, enabling its application to all variants, including exonic and intronic nucleotide variants, as well as structural variants.

Review
][104] Novel CRISPR-based molecular tools have also emerged as a therapeutic option for STGD1 (figure 3B). 105Recently, gene editing via CRISPR/Cas9 has been employed to correct pathogenic variants of ABCA4 in human iPSCs (hiPSC) for STGD1 patients. 106However, there are potential safety concerns associated with gene editing methods being developed for STGD1, namely the introduction of double-stranded breaks (DSBs) in the genome during editing.Gene editing systems such as CRISPR/ Cas9 create DSBs, which run the risk of triggering error-prone endogenous DNA repair mechanisms that could otherwise cause unwanted effects. 107 108However, systems that exploit transposon-based mutagenesis-such as fish-derived Sleeping Beauty 109 110 and insect-derived PiggyBac 111 -may circumvent this issue.A potential drawback for such methods is that the DNA recognition sequence may be found throughout the human genome and thus the gene would not be targeted to a specific site.Thus, an ideal transposon-based system would be one that is mammal-derived and absent of immunogenic effects, with the capability to insert genetic material of unlimited size at a sitespecific genomic target.
By combining features of the above systems, there is potential for developing much needed novel gene therapies that can transport a larger size DNA cargo (and avoid the introduction of DSBs) for STGD1 and other common IRDs such as USH2A-associated retinitis pigmentosa and Usher syndrome.For example, a novel DNA integrating platform developed by SalioGen Therapeutics-Gene Coding-combines many of the above-mentioned features (figure 3B).The technology uses a tissue-specific and cell-specific nanoparticle (NP) to co-encapsulate mRNA encoding a synthetic bioengineered, mammalian transposase and a DNA element containing the gene of interest for a specific disease target.Notably, the DNA element can contain large genetic cargos, such as ABCA4, or a combination of several genetic factors, since the NP does not have size limitations.
Several potential benefits of this type of technology are currently under investigation.First, NPs that target specific cell types such as photoreceptors and RPE are being developed. 112econd, the NP capability to deliver large gene cargos is being exploited to deliver single or multiple genetic components and regulatory elements to control gene expression.Third, the non-viral nature of the DNA integration system may decrease the immunogenicity seen with viral delivery systems.Finally, in contrast to AAV therapies and non-viral gene editing technologies and gene therapies, the transposase avoids unwanted genomic effects by avoiding DSBs 113 while integrating therapeutic genes at polynucleotide sites in the genome.All of these potential attributes may be important in treating degenerative retinal disorders such as STGD1, which is caused by multiple pathogenic variants in large genes.

CONCLUSIONS
STGD1 is one of the most common IRDs, presenting in childhood, early adulthood and in later life.This ABCA4-associated retinopathy is highly heterogeneous both clinically and genetically.The deep clinical and genetic characterisation that has been undertaken over the last 15 years has improved understanding of underlying disease mechanisms, natural history and outcome metrics, allowing multiple therapeutic trials to be conducted.Further trials are anticipated, including pharmacological in the immediate term, with innovations towards the development of novel gene therapy approaches on the horizon.

ReviewFigure 3
Figure 3 Current and future treatment agents for STGD1 A schematic showing (A) current pharmacological STGD1 treatment agents and (B) novel genetic therapies for STGD1.(A) Schematic showing the normal visual cycle (pink) and failure of transport due to ABCA4 dysfunction (blue).Agents (RPE65 inhibitors, deuterated Vitamin A, RBP4 antagonists) lower the formation of toxic products of the retinoid cycle by enzymatic inhibition, reducing delivery of vitamin A, or antagonising the retinoid binding protein 4 (RBP4).(B) Schematic showing non-integrating episomal andintegrating nuclear gene therapies.The ABCA4 gene is expressed in photoreceptors and the transporter is localised at the rim of rod and cone photoreceptors at the outer segment (OS), which connects to the inner segment (IS) via connecting cilium (CC).To target disordered transport due to ABCA4 dysfunction, adeno-associated virus (AAV) therapies deliver the large 6.4 kb ABCA4 gene (>4.7 kb AAV cargo limit) to the nucleus by splicing together fragments of the ABCA4 gene, wherein the transgene remains in an episomal state.Gene editing therapies cut or alter single nucleotide(s) within the ABCA4 gene via techniques such as CRISPR-Cas, which targets specific variants.Gene coding replaces the entire ABCA4 gene via an engineered transposase, enabling its application to all variants, including exonic and intronic nucleotide variants, as well as structural variants.
Substantial contributions to the conception or design of the work; or the acquisition, analysis, or interpretation of data for the work; KF, NW, YL, PY, YF-Y, JJH, JTL, DC, CC and MM.Drafting the work or revising it critically for important intellectual content; KF, NW, YL, PY, YF-Y, JJH, JTL, DC, CC and MM.Final approval of the version to be submitted; KF, NW, YL, PY, YF-Y, JJH, JTL, DC, CC and MM.Agreement to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved; KF, NW, YL, PY, YF-Y, JJH, JTL, DC, CC and MM.Funding KF, MM, YL and YF-Y are supported by grants from the National Institute for Health Research Biomedical Research Centre at Moorfields Eye Hospital NHS Foundation Trust and UCL Institute of Ophthalmology.MM is supported by The Wellcome Trust 2 (099173/Z/12/Z).NW is supported by funding from Tufts University School of Medicine.PY is supported by Foundation Fighting Blindness TRAP1 Award TA-NMT-0521-0803-OHSU-TRAP, grant P30 EY010572 from the National Institutes of Health (Bethesda, MD), the Malcolm M. Marquis, MD Endowed Fund for Innovation, and unrestricted departmental funding from Research to Prevent Blindness (New York, NY).DC is a full-time employee of AGTC.JJH and JTL are fulltime employees of SalioGen Therapeutics.Competing interests Disclosures/Conflicts of Interest: KF: Consultant (category C): Astellas Pharma, Kubota Pharmaceutical, Acucela, Novartis, Janssen, Sanofi, NightstaRx, Stargazer, SalioGen Therapeutics, Belite Bio, Alnylam, Restore Vision, FRESTKF: Clinical trial/Research support (category F): National Institute for Health and Care Research, Foundation Fighting Blindness, Janssen, Novartis, Janssen, AstellasPY: Consultant (category C): 4D Molecular Therapeutics, Adverum, AGTC, Annexon Bio, EcoR1, Exegenesis Bio, ExpertConnect, Foundation Fighting Blindness (SAB), Guidepoint, Iveric Bio, Janssen, MeiraGTx, Nanoscope Therapeutics (SAB), Otonomy, ProQR, Saliogen Therapeutics, TeamedOn, VederePY: Clinical trial/Research support (category F): 4D Molecular Therapeutics, Acucela, Atsena, AGTC, Biogen, Editas, Foundation Fighting Blindness, Iveric bio, Ocugen, ProQR, Reneuron, Sanofi, SparkNW: Consultant (category C): Complement Therapeutics, Nidek, SalioGen Therapeutics, Stealth, Syncona, TopconNW: Clinical trial/Research support (category F): Carl Zeiss Meditec, Heidelberg, NidekNW: N Waheed is a board member of Iolyx Therapeutics, a shareholder in Ocudyne, and a previous shareholder of Gyroscope Therapeutics.JH, JTL and CC: JH and JTL are currently full-time employees and stock option holders of SalioGen Therapeutics.C Clary is a former employee of SalioGen Therapeutics.DC: D Curtiss is a full-time employee and stock option holder of AGTC.YL, YF-Y: YL and YF-Y have no conflicts of interest to disclose.MM: Consultant (category C): Acucela, MeiraGTx, Janssen, Stargazer, Claris Bio, SalioGen Therapeutics, Belite Bio and Alnylam.MM holds equity in MeiraGTx.Patient consent for publication Not applicable.Provenance and peer review Not commissioned; externally peer reviewed.