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ATRX

ATRX, also known as , is a protein-coding located on the at position q21.1 that encodes a member of the family of remodelers, essential for regulating , structure, and genomic stability during development and . The ATRX protein, comprising 2,492 , functions primarily by partnering with the death domain-associated protein (DAXX) to deposit the variant H3.3 at telomeres, repetitive DNA regions, and transcription start sites, thereby facilitating ATP-dependent , DNA methylation maintenance, and resolution of structures to prevent replication stress and promote pathways such as . Mutations in ATRX, which spans approximately 281 kilobase pairs and contains 37 exons, are predominantly loss-of-function and underlie , an X-linked recessive disorder characterized by profound , distinctive craniofacial dysmorphisms (such as , a short triangular , and a tented upper lip), genital anomalies in affected males (including or ), , seizures, and due to in approximately 75% of cases. This syndrome, first described in the 1980s, affects hundreds of individuals worldwide with no known ethnic predilection, and inheritance follows X-linked patterns where hemizygous pathogenic variants in males lead to the full while carrier females are typically asymptomatic. Beyond neurodevelopmental disorders, ATRX alterations are recurrent in various cancers, including approximately 30% of pediatric gliomas and 11% of high-risk neuroblastomas, where they drive alternative lengthening of telomeres (ALT), genomic instability, and tumor progression, often correlating with improved response to therapies like in certain contexts.

Gene and Protein Overview

Genomic Location and Structure

The ATRX gene is located on the long arm of the human X chromosome at the cytogenetic band Xq21.1. It spans approximately 300 kilobases (kb) of genomic DNA and consists of 37 exons, with the gene oriented on the reverse strand from position 77,504,880 to 77,786,233 in the GRCh38 reference assembly. This organization was determined through sequencing efforts that mapped the exon-intron boundaries using vectorette PCR strategies. The ATRX gene undergoes , producing multiple isoforms, with the transcript (NM_000489.6) encoding a 2,492-amino-acid protein. At least 25 distinct transcripts have been annotated, arising from variations in inclusion, particularly in regions encoding the N-terminal and C-terminal domains, which contribute to functional diversity in chromatin regulation. ATRX exhibits strong evolutionary conservation across mammals, reflecting its essential role in genomic stability. The mouse ortholog, Atrx, located on the X chromosome at position 104,841,221-104,973,009 (GRCm39), shares approximately 88% identity in coding sequences with the human gene, enabling robust comparative studies in model organisms. A notable genomic feature of the ATRX gene is the presence of CpG islands in its promoter region, particularly spanning exon 1, which are subject to during in females. This epigenetic modification helps silence the gene on the inactive , contributing to dosage compensation and influencing expression patterns in a sex-specific manner.

Protein Composition and Domains

The ATRX protein is a large nuclear protein belonging to the family of remodelers, with a calculated molecular weight of approximately 280 kDa and consisting of 2492 in its primary isoform. This family membership is defined by its conserved / motifs that enable energy-dependent manipulation of structure. The overall architecture of ATRX features a modular organization, with distinct N-terminal, central, and C-terminal regions that contribute to its localization, binding specificity, and regulatory functions. Key structural domains include the N-terminal ADD (ATRX-DNMT3-DNMT3L) domain, spanning approximately 175–318, which comprises a GATA-like and a plant homeodomain (PHD)-like for specific recognition of tails, particularly those unmodified at 4 or trimethylated at 9. The central region harbors the SNF2-like / domain ( ~1175–2205), characterized by seven conserved motifs that facilitate and DNA translocation during . At the C-terminus lies the ATRX-specific domain, integrated within or adjacent to the core (including the C-terminal domain-like region, ~1766–1918), which supports direct binding to DNA structures such as G-quadruplexes and contributes to substrate specificity. The N-terminal hydrophilic segment, enriched in serine, , and glutamine residues (~40% composition), includes a localization signal that directs ATRX to the and heterochromatic regions, as well as coiled-coil motifs that mediate interactions with partner proteins. Post-translational modifications, particularly on serine residues, regulate ATRX's activity and localization; these occur predominantly during and may promote its dissociation from to facilitate . Such modifications are cell cycle-dependent and target multiple serine sites across the protein, influencing its stability and interactions without altering the core domain architecture.

Molecular Functions

Chromatin Remodeling Mechanisms

ATRX functions as an ATP-dependent chromatin remodeler within the SWI/SNF family, utilizing its central SNF2-like helicase domain to drive nucleosome translocation along DNA. This domain, characteristic of the SNF2 subfamily, harnesses the energy from ATP hydrolysis to disrupt histone-DNA contacts, enabling the physical repositioning of nucleosomes and thereby enhancing chromatin accessibility to regulatory factors. Specifically, ATRX translocates unidirectionally along the DNA, starting from the edge of the nucleosome, which facilitates the sliding of the histone octamer without ejecting it from the DNA. The remodeling mechanism involves the formation of DNA loops as ATRX progresses, powered by sequential ATP binding and hydrolysis cycles that propagate conformational changes through the helicase domains. This process mobilizes the along the DNA, allowing for local decompaction of chromatin structures and exposure of underlying DNA sequences. In vitro translocation assays using recombinant ATRX have confirmed this ATP-dependent movement across linear DNA substrates, with disease-associated mutations in the SNF2 domain impairing translocation efficiency while preserving ATP hydrolysis in some cases. ATRX exhibits a marked preference for GC-rich heterochromatic regions, including ribosomal DNA (rDNA) repeats and pericentromeric satellite sequences, where it binds to structures to prevent their interference with chromatin organization. Chromatin immunoprecipitation studies reveal enriched ATRX occupancy at these repetitive, GC-skewed loci, correlating with allele-specific expression patterns influenced by repeat array size. This targeting specificity underscores ATRX's role in maintaining the structural integrity of highly compacted . Experimental evidence from assays further supports ATRX's decompacting activity: purified ATRX displays nucleosome-stimulated activity, approximately 1- to 2-fold higher than that of complexes, and remodels mononucleosomes by altering their DNase I footprint, particularly at the DNA entry site. Additionally, ATRX mediates ATP-dependent displacement of triple-helix structures, demonstrating its properties without helicase-like duplex unwinding. These assays highlight ATRX's capacity to loosen packing, facilitating access for replication and transcription machinery in repetitive regions.

Histone Deposition and Epigenetic Regulation

ATRX cooperates with the histone chaperone DAXX to deposit the histone variant H3.3 into , particularly at telomeric and pericentromeric regions. This complex facilitates the replication-independent incorporation of H3.3-H4 dimers, which helps maintain structure in these repetitive sequences prone to instability. The ATRX-DAXX partnership ensures targeted deposition by recognizing specific DNA features, such as structures, thereby stabilizing s in areas with high nucleosome turnover. Disruption of this cooperation, as seen in ATRX mutations, leads to defective H3.3 loading and decondensation at these loci. In regulating epigenetic marks, ATRX prevents aberrant H3.3 deposition that could disrupt integrity, thereby maintaining and modifications essential for . By promoting H3.3 incorporation alongside H3K9 trimethylation, ATRX shields repetitive elements from demethylation-induced instability during cellular stress, such as DNA hypomethylation. Similarly, ATRX influences dynamics at facultative , where loss of ATRX function shifts silencing marks and impairs long-term epigenetic . This regulatory role underscores ATRX's contribution to stability, preventing ectopic mark spreading that could activate silenced genes. ATRX also shapes DNA patterns at imprinted loci and during X-chromosome inactivation (XCI), linking deposition to broader epigenetic control. At imprinted regions, ATRX-dependent H3.3 deposition sustains memory, ensuring parent-of-origin-specific and expression; its absence results in derepression and altered profiles. In XCI, ATRX is crucial for imprinted inactivation in extraembryonic tissues, where mutations cause skewed patterns and abnormal development due to disrupted at X-linked loci. These functions highlight ATRX's integration of variant placement with DNA modification for stable epigenetic inheritance. A study from has revealed that ATRX undergoes liquid-liquid (LLPS) to form biomolecular condensates in neural cells, enhancing its localized chaperone activity. In neural cells, ATRX condensates, driven by its intrinsically disordered region, concentrate at super-enhancers to recruit coactivators like P300 and facilitate precise H3.3 deposition for neural identity maintenance. This phase-separated state promotes and , with disruptions impairing neuronal fate commitment. Such findings elucidate how ATRX's compartmentalization supports targeted epigenetic modifications in neurodevelopment.

Biological Roles

Telomere Maintenance and ALT Pathway

The ATRX-DAXX complex plays a crucial role in telomere maintenance by depositing the histone variant H3.3 at telomeric , which helps establish repressive structures and ensures telomere stability. This deposition suppresses (HR) at telomeres by resolving replication stress and reducing transcription of telomere repeat-containing (TERRA), thereby preventing inappropriate telomere elongation. Additionally, ATRX interacts with complex components, such as TRF2, to facilitate proper binding and capping of telomeres, further safeguarding against genomic instability. Loss of ATRX function disrupts H3.3 incorporation at telomeres, leading to telomere dysfunction-induced foci (TIFs), which are markers of DNA damage response activation at chromosome ends. This dysfunction promotes the activation of the alternative lengthening of telomeres (ALT) pathway, a telomerase-independent mechanism that relies on break-induced replication (BIR) to elongate telomeres. In ATRX-deficient cells, increased replication fork stalling and R-loop formation exacerbate telomeric damage, shifting repair toward BIR-mediated synthesis. The mechanism involves between telomeric repeats, often initiated at double-strand breaks or stalled forks, resulting in conservative that produces ultra-long telomeres characteristic of this pathway. is observed in approximately 10% of human cancers, where it enables replicative immortality without activity. Diagnostic hallmarks of ALT include C-circles, extrachromosomal telomeric DNA circles generated during BIR, which serve as specific biomarkers for pathway activation. Recent research from 2025 has linked ATRX mutations to ALT activation in pancreatic neuroendocrine tumors (PanNETs), particularly in functioning subtypes like insulinomas and glucagonomas, where these alterations correlate with aggressive disease progression. In these tumors, ATRX loss promotes as evidenced by elevated C-circle levels, providing a potential diagnostic and prognostic marker independent of DAXX mutations.

Gene Expression and Developmental Processes

ATRX plays a crucial role in retrotransposons and repetitive elements during embryonic development to maintain genomic stability. By promoting the formation of inaccessible at these sites, ATRX prevents ectopic insertions that could disrupt gene regulation and lead to instability, particularly in embryonic stem cells where is low. The DAXX/ATRX complex further safeguards tandem repeats by depositing variant H3.3, ensuring repression when methylation defenses are insufficient. This mechanism is essential for proper embryogenesis, as loss of ATRX leads to derepression of repeats and associated developmental defects. In neural development, ATRX influences fate through the formation of . A 2025 study demonstrated that ATRX undergoes liquid-liquid (LLPS) via its intrinsically disordered region, creating dynamic condensates in neural cells (hNPCs) that recruit co-activators and maintain identity. Disruption of these condensates impairs the balance between self-renewal and , highlighting ATRX's role in chromatin organization for neural lineage commitment. ATRX also regulates HOX gene expression critical for neuronal differentiation. Loss of ATRX in mouse models upregulates HOX cluster genes, such as , inhibiting differentiation pathways and promoting aberrant neuronal lineage progression. In knockout mice, this manifests as defects in survival and differentiation, particularly in the and , where conditional inactivation during embryogenesis results in selective loss of amacrine and cells due to impaired post-specification survival. These findings underscore ATRX's necessity for precise transcriptional control during corticogenesis and neuronal maturation. As an X-linked gene, ATRX exhibits biallelic expression patterns, escaping inactivation in various tissues including the . This escape ensures sufficient ATRX levels in females for neurodevelopmental processes, with expression from both active and inactive X chromosomes observed in fibroblasts and neural contexts, contributing to dosage compensation and preventing manifestations in carriers.

Clinical and Pathological Significance

ATRX Syndrome and Inherited Disorders

, also known as , is a rare primarily affecting males and characterized by severe , distinctive dysmorphic facial features, genital anomalies, and (a form of ). The syndrome was first linked to in 1981 through observations of alongside mental retardation in affected individuals, with the condition formally delineated and named ATR-X in 1990 based on five unrelated cases exhibiting non-deletion forms of . Clinical manifestations include profound developmental delay with absent or limited speech, , , and facial traits such as , a tented upper lip, and midface hypoplasia; genital abnormalities like and ambiguous genitalia are common, while presents as mild microcytic with hemoglobin H inclusions in approximately 75% of cases, often not requiring specific treatment. The disorder arises from pathogenic variants in the located at Xq21.1, with mutations predominantly consisting of loss-of-function missense or frameshift alterations in the or domains, resulting in reduced or absent ATRX protein expression. Hundreds of pathogenic variants have been reported, with missense variants accounting for about 75% and frequently clustering in exons 7-9 of the region; these changes disrupt protein function without typically causing large deletions. follows an X-linked pattern, with hemizygous males experiencing severe phenotypes due to the single , while carrier females often exhibit skewed X-chromosome inactivation to mitigate effects, though rare symptomatic females have been documented. Diagnosis is established through molecular genetic testing, including and deletion/duplication studies of the ATRX gene in males with a 46, karyotype who present with the characteristic clinical triad of , , and dysmorphic features; is available for at-risk pregnancies. Management is supportive and multidisciplinary, focusing on addressing through educational interventions, managing seizures or gastrointestinal issues if present, surgical correction of genital anomalies, and routine monitoring for growth, development, and potential complications like or urogenital defects, as no curative therapy exists.

Somatic Mutations in Cancer

Somatic mutations in the ATRX gene are recurrently identified across multiple cancer types, with notably high frequencies in pediatric high-grade gliomas (up to 30%), neuroblastomas (particularly in high-risk cases, where they occur in approximately 8-9%), and sarcomas (8-13% in subtypes with complex cytogenetics). In neuroblastomas, ATRX mutations are mutually exclusive with MYCN amplification, distinguishing a subset of tumors characterized by rather than telomerase-driven immortality. These mutations typically involve loss-of-function alterations, such as truncating variants or deletions, leading to ATRX protein deficiency that disrupts and epigenetic stability. ATRX mutations drive oncogenic processes by activating the pathway for telomere maintenance, facilitating immune evasion through reduced innate immune signaling, and promoting tumor progression via increased genomic instability and proliferation. In neuroblastomas, recent analyses indicate that ATRX alterations confer an immunogenic , marked by enhanced infiltration and potential activation of interferon-related pathways, though this may paradoxically support chronic metastatic disease. Experimental models demonstrate that ATRX loss accelerates tumor growth and , particularly in soft tissue sarcomas, by impairing and altering signaling. Prognostically, ATRX loss in glioblastoma correlates with reduced overall survival in preclinical models and select cohorts, reflecting heightened genetic instability and ALT dependence, while serving as a reliable biomarker for ALT-positive tumors across gliomas and other malignancies. Therapeutically, ATRX-deficient cancers exhibit synthetic lethality with PARP inhibitors due to compromised DNA damage response and homologous recombination defects, as evidenced by increased sensitivity in glioblastoma and neuroblastoma cell lines. Ongoing research highlights this vulnerability, positioning PARP inhibition as a promising strategy for ATRX-mutated tumors.

Protein Interactions and Regulation

Key Interacting Partners

ATRX primarily interacts with the death domain-associated protein (DAXX) to form a stable complex that facilitates the deposition of the variant H3.3 at heterochromatic regions, including telomeres and pericentromeric repeats. This ATRX-DAXX-H3.3 complex is essential for replication-independent assembly, where DAXX acts as a specific chaperone for H3.3, and ATRX provides the ATP-dependent remodeling activity to incorporate the into nucleosomes. The ATRX protein also binds heterochromatin protein 1 (HP1) isoforms through its ADD domain, which recognizes the histone H3 tail modified by H3K9 trimethylation (H3K9me3) in conjunction with unmethylated H3K4. This interaction targets ATRX to heterochromatic loci, enhancing its recruitment and stabilizing chromatin compaction at repetitive DNA elements. The cooperative binding of the ATRX ADD domain and HP1 forms a tripartite module that spans adjacent nucleosomes, promoting heterochromatin maintenance. ATRX associates with the protein ZNF274 to preserve enrichment at the 3' exons of zinc finger genes, atypical domains characterized by high GC content and low transcriptional activity. Depletion of either ATRX or ZNF274 leads to reduced levels at these sites, resulting in increased DNA damage and genomic instability, underscoring their role in silencing and protecting repetitive elements. Similarly, ATRX interacts with methyl-CpG-binding domain protein 5 (MBD5) in the context of maintenance at repetitive sequences, contributing to stability in neurodevelopmental processes. Additionally, ATRX engages with enhancer of zeste homolog 2 (), the catalytic subunit of the Polycomb repressive complex 2 (PRC2), to direct PRC2 binding to RNA and specific polycomb target genes. This interaction facilitates H3K27 trimethylation-mediated repression at developmental loci, with ATRX acting as a scaffold for PRC2 recruitment independent of its function. Loss of ATRX disrupts this association, altering polycomb-dependent .

Regulatory Pathways and Modifiers

Post-translational modifications play a critical role in controlling ATRX stability, localization, and activity. Ubiquitination targets ATRX for proteasomal , particularly in viral infection contexts where complexes, such as those involving adenovirus E1B-55K/E4orf6, reduce ATRX levels to facilitate replication. This modification affects nuclear retention and overall , preventing excessive accumulation that could inhibit viral . SUMOylation of ATRX occurs in proliferating cells. progression also regulates ATRX through events. ATRX undergoes cell cycle-dependent , with increased modification observed during G2/M phase, correlating with its association with the nuclear matrix and . While specific kinases like CDK1 have been implicated in broader G2/M regulation, at 'SDT-like' motifs in ATRX enhances its binding to the MRN complex, supporting and replication fork stability during . This temporal control ensures ATRX's role in function and chromosome segregation peaks when needed. ATRX supports DNA damage response () pathways by facilitating ATM-dependent through maintenance of H3K9me3. Its loss impairs ATM-associated repair, resulting in increased replication stress and enhanced sensitivity to in cells.

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