https://wires.onlinelibrary.wiley.com/journal/26929368?af=R Table of Contents for WIREs Mechanisms of Disease. List of articles from both the latest and EarlyView issues. en-US wileyonlinelibrary@wiley.com (Wiley Interdisciplinary Reviews) Thu, 11 Jun 2026 07:58:42 +0000 Thu, 11 Jun 2026 07:58:42 +0000 Atypon® Literatum™ https://validator.w3.org/feed/docs/rss2.html 10080 Wiley: WIREs Mechanisms of Disease: Table of Contents Wiley WIREs Mechanisms of Disease https://wires.onlinelibrary.wiley.com/pb-assets/journal-banners/26929368.jpg https://wires.onlinelibrary.wiley.com/journal/26929368?af=R https://wires.onlinelibrary.wiley.com/doi/10.1002/wsbm.70006?af=R Tue, 10 Feb 2026 00:00:00 -0800 2026-02-10T12:00:00-08:00 Wiley: WIREs Mechanisms of Disease: Table of Contents Thu, 01 Jan 2026 00:00:00 -0800 Thu, 01 Jan 2026 00:00:00 -0800 10.1002/wsbm.70006 WIREs Mechanisms of Disease, Volume 18, Issue 1, January/February 2026. ISSUE INFORMATION Issue Information 10.1002/wsbm.70006 WIREs Mechanisms of Disease 10.1002/wsbm.70006 https://wires.onlinelibrary.wiley.com/doi/10.1002/wsbm.70006?af=R ISSUE INFORMATION 18 1 https://wires.onlinelibrary.wiley.com/doi/10.1002/wsbm.70007?af=R Tue, 10 Feb 2026 00:00:00 -0800 2026-02-10T12:00:00-08:00 Wiley: WIREs Mechanisms of Disease: Table of Contents Thu, 01 Jan 2026 00:00:00 -0800 Thu, 01 Jan 2026 00:00:00 -0800 10.1002/wsbm.70007 WIREs Mechanisms of Disease, Volume 18, Issue 1, January/February 2026. This graphic summarizes the key themes of this review. The left panel outlines the major clinical features of Nager syndrome in humans. The middle panel highlights phenotypes observed across different experimental models, including Xenopus, zebrafish, and mouse, which recapitulate core aspects of the human disorder while also exhibiting model‐specific features resulting from sf3b4 deficiency. The right panel illustrates a proposed pathogenic framework in which SF3B4 variants lead to spliceosomal dysfunction and preferential exon skipping, particularly affecting AT‐rich and GC‐poor exons. These splicing perturbations impair neural crest cell (NCC) proliferation, survival, and function, ultimately resulting in multisystem developmental defects. The image was prepared by the Adobe Illustrator and Microsoft PowerPoint software. ABSTRACT Nager syndrome (NS) is a rare congenital disorder primarily characterized by mandibulofacial dysostosis and upper limb anomalies. Pathogenic variants in SF3B4, which encodes a core spliceosomal component, represent the primary known genetic cause of NS. This review synthesizes recent findings from cellular, zebrafish, Xenopus, and mouse models to elucidate how SF3B4 deficiency perturbs neural crest cell (NCC) biology and multi‐tissue development. Loss of SF3B4 induces widespread splicing abnormalities, with preferential exon skipping affecting AT‐rich and GC‐poor exons, thereby altering the expression of genes critical for NCC survival, proliferation, migration, and lineage specification. These cellular defects are further exacerbated by oxidative stress and activation of the p53 pathway, resulting in a broad spectrum of developmental abnormalities involving craniofacial, cardiac, skeletal, and sensory (auditory and ocular) systems. Together, these findings highlight the essential role of SF3B4 in coordinating early morphogenesis. Cross‐species comparisons reveal conserved NCC vulnerabilities alongside model‐specific phenotypes, highlighting the challenge of linking individual splicing alterations to distinct structural outcomes in NS. Future research directions include defining tissue‐specific SF3B4‐dependent splicing targets, developing human induced pluripotent stem cell–derived models, and exploring therapeutic strategies aimed at restoring splicing homeostasis or compensating for disrupted developmental signaling pathways. This article is categorized under: Congenital Diseases > Molecular and Cellular Physiology Congenital Diseases > Genetics/Genomics/Epigenetics Congenital Diseases > Stem Cells and Development <img src="https://wires.onlinelibrary.wiley.com/cms/asset/e7a5d3f7-28d9-4417-aca5-541a8183d9c9/wsbm70007-toc-0001-m.png" alt="Nager Syndrome Revisited: Integrating In Vivo and In Vitro Models to Decipher SF3B4-Dependent Tissue Coordination"/> <p>This graphic summarizes the key themes of this review. The left panel outlines the major clinical features of Nager syndrome in humans. The middle panel highlights phenotypes observed across different experimental models, including <i>Xenopus</i>, zebrafish, and mouse, which recapitulate core aspects of the human disorder while also exhibiting model-specific features resulting from <i>sf3b4</i> deficiency. The right panel illustrates a proposed pathogenic framework in which <i>SF3B4</i> variants lead to spliceosomal dysfunction and preferential exon skipping, particularly affecting AT-rich and GC-poor exons. These splicing perturbations impair neural crest cell (NCC) proliferation, survival, and function, ultimately resulting in multisystem developmental defects. The image was prepared by the Adobe Illustrator and Microsoft PowerPoint software.</p> <br/> <h2>ABSTRACT</h2> <p>Nager syndrome (NS) is a rare congenital disorder primarily characterized by mandibulofacial dysostosis and upper limb anomalies. Pathogenic variants in <i>SF3B4</i>, which encodes a core spliceosomal component, represent the primary known genetic cause of NS. This review synthesizes recent findings from cellular, zebrafish, <i>Xenopus</i>, and mouse models to elucidate how <i>SF3B4</i> deficiency perturbs neural crest cell (NCC) biology and multi-tissue development. Loss of <i>SF3B4</i> induces widespread splicing abnormalities, with preferential exon skipping affecting AT-rich and GC-poor exons, thereby altering the expression of genes critical for NCC survival, proliferation, migration, and lineage specification. These cellular defects are further exacerbated by oxidative stress and activation of the p53 pathway, resulting in a broad spectrum of developmental abnormalities involving craniofacial, cardiac, skeletal, and sensory (auditory and ocular) systems. Together, these findings highlight the essential role of <i>SF3B4</i> in coordinating early morphogenesis. Cross-species comparisons reveal conserved NCC vulnerabilities alongside model-specific phenotypes, highlighting the challenge of linking individual splicing alterations to distinct structural outcomes in NS. Future research directions include defining tissue-specific <i>SF3B4</i>-dependent splicing targets, developing human induced pluripotent stem cell–derived models, and exploring therapeutic strategies aimed at restoring splicing homeostasis or compensating for disrupted developmental signaling pathways.</p> <p>This article is categorized under: Congenital Diseases &gt; Molecular and Cellular Physiology Congenital Diseases &gt; Genetics/Genomics/Epigenetics Congenital Diseases &gt; Stem Cells and Development </p> Jingru Qin, Zulvikar Syambani Ulhaq, William Ka Fai Tse FOCUS ARTICLE Nager Syndrome Revisited: Integrating In Vivo and In Vitro Models to Decipher SF3B4‐Dependent Tissue Coordination 10.1002/wsbm.70007 WIREs Mechanisms of Disease 10.1002/wsbm.70007 https://wires.onlinelibrary.wiley.com/doi/10.1002/wsbm.70007?af=R FOCUS ARTICLE 18 1