Stargardt病个性化治疗的进展

Pub Date : 2023-10-06 DOI:10.1080/17469899.2023.2268289
Di Huang, Sam McLenachan, Fred K. Chen
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These breakthroughs facilitate the application of gene expression modulation technologies, ushering in a new era of personalized therapeutics. By targeting the ABCA4 gene and manipulating its expression, tailored treatments can address ABCA4-associated STGD1, offering enhanced efficacy and precise interventions based on the individual’s genetic profile. These advancements provide hope to those affected by STGD1, with improved treatment options and the potential to prevent vision loss. The convergence of genetic analysis breakthroughs and gene expression modulation technologies revolutionizes our understanding and treatment of inherited disorders, unlocking a promising frontier in personalized therapeutics. 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Article highlightsAutosomal recessive Stargardt disease (STGD1) is a common monogenic inherited retinal dystrophy that leads to bilateral central vision loss and is responsible for 12% of IRD-related blindness.The spectrum of retinopathy associated with STGD1 includes childhood-onset cone-rod dystrophy, late-onset STGD1 with foveal sparing, and rapid-onset chorioretinopathy phenotype.STGD1 is caused by bi-allelic variants in the ATP-binding cassette transporter subfamily A4 gene (ABCA4) gene, which encodes the ABCA4 protein responsible for importing specific retinoid compounds in photoreceptor cells.Variable accumulation of cytotoxic lipofuscin-related fluorophores, such as A2E, is determined by combined deleterious effect of the biallelic ABCA4 variants and contributes to phenotypic variation.Antisense oligonucleotide (AONs) technology is being used to modify gene expression by targeting specific sequences and correcting splicing defects caused by ABCA4 variants, with particular observed in addressing pseudoexon inclusion resulting from by deep-intronic variants and exon elongation/skipping resulting from near-exon variants.Base editing and prime editing hold promise for addressing missense variants in the ABCA4 gene and could potentially target a significant proportion of ABCA4 variants associated with STGD1.Translational readthrough-inducing drugs (TRIDs) are being explored as a therapeutic strategy for STGD1 caused by nonsense variants, which account for approximately 12% of genetic diseases.Declaration of interestF.K. Chen and S. McLenachan are listed as co-inventor and co-contributor (respectively) on the international patent WO/2020/237294 (filed on 25 May 2020) for an antisense oligonucleotide drug treatment for retinitis pigmentosa. F.K. Chen is a consultant for PYC Therapeutics, Apellis and Janssen.The authors have no other relevant affiliations or financial involvement with any organization or entity with a financial interest in or financial conflict with the subject matter or materials discussed in the manuscript apart from those disclosed.Reviewer disclosuresA reviewer on this manuscript has disclosed that they are a consultant for Novartis and Janssen, unrelated to this manuscript. Peer reviewers on this manuscript have no other relevant financial relationships or otherwise to disclose.Additional informationFundingThis paper was funded by the Channel 7 Telethon Trust; the Future Health Research and Innovation Fund; the Macular Disease Foundation Australia; the National Health & Medical Research Council of Australia, grants: GNT1116360, GNT1188694, GNT1054712, RF1142962; Retina Australia; and the McCusker Charitable Foundation.","PeriodicalId":0,"journal":{"name":"","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-10-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Advances towards personalized therapies for Stargardt disease\",\"authors\":\"Di Huang, Sam McLenachan, Fred K. 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Article highlightsAutosomal recessive Stargardt disease (STGD1) is a common monogenic inherited retinal dystrophy that leads to bilateral central vision loss and is responsible for 12% of IRD-related blindness.The spectrum of retinopathy associated with STGD1 includes childhood-onset cone-rod dystrophy, late-onset STGD1 with foveal sparing, and rapid-onset chorioretinopathy phenotype.STGD1 is caused by bi-allelic variants in the ATP-binding cassette transporter subfamily A4 gene (ABCA4) gene, which encodes the ABCA4 protein responsible for importing specific retinoid compounds in photoreceptor cells.Variable accumulation of cytotoxic lipofuscin-related fluorophores, such as A2E, is determined by combined deleterious effect of the biallelic ABCA4 variants and contributes to phenotypic variation.Antisense oligonucleotide (AONs) technology is being used to modify gene expression by targeting specific sequences and correcting splicing defects caused by ABCA4 variants, with particular observed in addressing pseudoexon inclusion resulting from by deep-intronic variants and exon elongation/skipping resulting from near-exon variants.Base editing and prime editing hold promise for addressing missense variants in the ABCA4 gene and could potentially target a significant proportion of ABCA4 variants associated with STGD1.Translational readthrough-inducing drugs (TRIDs) are being explored as a therapeutic strategy for STGD1 caused by nonsense variants, which account for approximately 12% of genetic diseases.Declaration of interestF.K. 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引用次数: 0

摘要

abca4相关的Stargardt病(STGD1)导致双侧中央视力丧失,是12%的遗传性视网膜疾病相关失明的原因。由于缺乏经批准的治疗方法,因此迫切需要有效的治疗方法。本综述探讨了STGD1的个性化治疗,重点是治疗替代剪接、基因组编辑和翻译读取技术。截至2023年7月,通过PubMed进行文献检索。测序技术取得了重大进展,揭示了abca4基因座的复杂性。综合功能分析现在能够确定不确定意义的abca4变异的致病性。这些突破促进了基因表达调节技术的应用,开创了个性化治疗的新时代。通过靶向ABCA4基因并操纵其表达,量身定制的治疗可以针对ABCA4相关的STGD1,提供基于个体遗传谱的增强疗效和精确干预。这些进步为STGD1患者带来了希望,改善了治疗选择,并有可能预防视力丧失。基因分析的突破和基因表达调节技术的融合彻底改变了我们对遗传性疾病的理解和治疗,为个性化治疗开辟了一个充满希望的前沿。这种针对STGD1的变革性方法有望在其他遗传疾病中取得类似突破。关键词:abca4遗传性视网膜疾病青少年黄斑营养不良个性化治疗三义寡核苷酸治疗替代剪接基因编辑crispr碱基编辑引物编辑免责声明作为对作者和研究人员的服务,我们提供此版本的接受稿件(AM)。在最终出版版本记录(VoR)之前,将对该手稿进行编辑、排版和审查。在制作和印前,可能会发现可能影响内容的错误,所有适用于期刊的法律免责声明也与这些版本有关。常染色体隐性Stargardt病(STGD1)是一种常见的单基因遗传性视网膜营养不良,可导致双侧中央视力丧失,并导致12%的ird相关失明。与STGD1相关的视网膜病变包括儿童期发病的锥杆营养不良、伴中央凹保留的迟发性STGD1和快速发病的脉络膜视网膜病变表型。STGD1是由atp结合盒转运蛋白亚家族A4基因(ABCA4)基因的双等位变异引起的,该基因编码ABCA4蛋白,负责在光感受器细胞中输入特定的类视黄醇化合物。细胞毒性脂褐素相关荧光团(如A2E)的可变积累是由双等位基因ABCA4变异的综合有害作用决定的,并有助于表型变异。反义寡核苷酸(AONs)技术被用于修饰基因表达,通过靶向特定序列和纠正由ABCA4变异引起的剪接缺陷,特别是在解决由深内含子变异引起的假外显子包含和由近外显子变异引起的外显子延伸/跳变。碱基编辑和引物编辑有望解决ABCA4基因中的错义变异,并可能潜在地靶向与STGD1相关的大量ABCA4变异。翻译读透诱导药物(TRIDs)正在被探索作为无义变异引起的STGD1的治疗策略,无义变异约占遗传疾病的12%。利益声明书Chen和S. McLenachan分别被列为国际专利WO/2020/237294(于2020年5月25日提交)的共同发明人和共同贡献者,该专利用于治疗视网膜色素变性的反义寡核苷酸药物。F.K. Chen是PYC Therapeutics, Apellis和Janssen的顾问。除了披露的内容外,作者与任何组织或实体没有其他相关关系或财务参与,这些组织或实体与稿件中讨论的主题或材料有经济利益或经济冲突。审稿人披露本文的一位审稿人披露,他们是诺华公司和杨森公司的顾问,与本文无关。本文的同行审稿人没有其他相关的财务关系或其他需要披露的信息。本文由第七频道telthon信托基金资助;未来健康研究及创新基金;澳大利亚黄斑疾病基金会;澳大利亚国家卫生与医学研究委员会,资助:GNT1116360, GNT1188694, GNT1054712, RF1142962;视网膜澳大利亚;以及麦卡斯克慈善基金会。
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Advances towards personalized therapies for Stargardt disease
ABSTRACTIntroduction ABCA4-associated Stargardt disease (STGD1) leads to bilateral central vision loss and is responsible for 12% of inherited retinal disease-related blindness.The lack of approved treatments highlights the urgent need for effective therapies.Areas covered This review explores personalized treatments for STGD1, focusing on therapeutic alternative splicing, genome editing, and translational read-through technologies. Literature searches as of July 2023 were undertaken via PubMed.Expert opinion Significant progress has been made in sequencing technology revealing the complexities of theABCA4 locus. Comprehensive functional assays now enable the determination of pathogenicity for ABCA4variants of uncertain significance. These breakthroughs facilitate the application of gene expression modulation technologies, ushering in a new era of personalized therapeutics. By targeting the ABCA4 gene and manipulating its expression, tailored treatments can address ABCA4-associated STGD1, offering enhanced efficacy and precise interventions based on the individual’s genetic profile. These advancements provide hope to those affected by STGD1, with improved treatment options and the potential to prevent vision loss. The convergence of genetic analysis breakthroughs and gene expression modulation technologies revolutionizes our understanding and treatment of inherited disorders, unlocking a promising frontier in personalized therapeutics. This transformative approach to STGD1 holds promise for similar breakthroughs in other inherited conditions.KEYWORDS: ABCA4inherited retinal diseasejuvenile macular dystrophypersonalized therapeuticsantisense oligonucleotidestherapeutic alternative splicinggene editingCRISPRbase editorprime editingDisclaimerAs a service to authors and researchers we are providing this version of an accepted manuscript (AM). Copyediting, typesetting, and review of the resulting proofs will be undertaken on this manuscript before final publication of the Version of Record (VoR). During production and pre-press, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal relate to these versions also. Article highlightsAutosomal recessive Stargardt disease (STGD1) is a common monogenic inherited retinal dystrophy that leads to bilateral central vision loss and is responsible for 12% of IRD-related blindness.The spectrum of retinopathy associated with STGD1 includes childhood-onset cone-rod dystrophy, late-onset STGD1 with foveal sparing, and rapid-onset chorioretinopathy phenotype.STGD1 is caused by bi-allelic variants in the ATP-binding cassette transporter subfamily A4 gene (ABCA4) gene, which encodes the ABCA4 protein responsible for importing specific retinoid compounds in photoreceptor cells.Variable accumulation of cytotoxic lipofuscin-related fluorophores, such as A2E, is determined by combined deleterious effect of the biallelic ABCA4 variants and contributes to phenotypic variation.Antisense oligonucleotide (AONs) technology is being used to modify gene expression by targeting specific sequences and correcting splicing defects caused by ABCA4 variants, with particular observed in addressing pseudoexon inclusion resulting from by deep-intronic variants and exon elongation/skipping resulting from near-exon variants.Base editing and prime editing hold promise for addressing missense variants in the ABCA4 gene and could potentially target a significant proportion of ABCA4 variants associated with STGD1.Translational readthrough-inducing drugs (TRIDs) are being explored as a therapeutic strategy for STGD1 caused by nonsense variants, which account for approximately 12% of genetic diseases.Declaration of interestF.K. Chen and S. McLenachan are listed as co-inventor and co-contributor (respectively) on the international patent WO/2020/237294 (filed on 25 May 2020) for an antisense oligonucleotide drug treatment for retinitis pigmentosa. F.K. Chen is a consultant for PYC Therapeutics, Apellis and Janssen.The authors have no other relevant affiliations or financial involvement with any organization or entity with a financial interest in or financial conflict with the subject matter or materials discussed in the manuscript apart from those disclosed.Reviewer disclosuresA reviewer on this manuscript has disclosed that they are a consultant for Novartis and Janssen, unrelated to this manuscript. Peer reviewers on this manuscript have no other relevant financial relationships or otherwise to disclose.Additional informationFundingThis paper was funded by the Channel 7 Telethon Trust; the Future Health Research and Innovation Fund; the Macular Disease Foundation Australia; the National Health & Medical Research Council of Australia, grants: GNT1116360, GNT1188694, GNT1054712, RF1142962; Retina Australia; and the McCusker Charitable Foundation.
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