Nuclear domain 10 (ND10), also referred to as nuclear bodies, are discrete interchromosomal accumulations of several proteins including promyelocytic leukemia protein (PML) and Sp100. In this study, we investigated the mechanism of ND10 assembly by identifying proteins that are essential for this process using cells lines that lack individual ND10-associated proteins. We identified the adapter protein Daxx and BML, the RecQ helicase missing in Bloom syndrome, as new ND10-associated proteins. PML, but not BLM or Sp100, was found to be responsible for the proper localization of all other ND10-associated proteins since they are dispersed in PML−/− cells. Introducing PML into this cell line by transient expression or fusion with PML-producing cells recruited ND10-associated proteins into de novo formed ND10 attesting to PMLs essential nature in ND10 formation. In the absence of PML, Daxx is highly enriched in condensed chromatin. Its recruitment to ND10 from condensed chromatin requires a small ubiquitin-related modifier (SUMO-1) modification of PML and reflects the interaction between the COOH-terminal domain of Daxx and PML. The segregation of Daxx from condensed chromatin in the absence of PML to ND10 by increased accumulation of SUMO-1–modified PML suggests the presence of a variable equilibrium between these two nuclear sites. Our findings identify the basic requirements for ND10 formation and suggest a dynamic mechanism for protein recruitment to these nuclear domains controlled by the SUMO-1 modification state of PML.
Telomeres repress the DNA damage response at the natural chromosome ends to prevent cell-cycle arrest and maintain genome stability. Telomeres are elongated by telomerase in a tightly regulated manner to ensure a sufficient number of cell divisions throughout life, yet prevent unlimited cell division and cancer development. Hoyeraal-Hreidarsson syndrome (HHS) is characterized by accelerated telomere shortening and a broad range of pathologies, including bone marrow failure, immunodeficiency, and developmental defects. HHS-causing mutations have previously been found in telomerase and the shelterin component telomeric repeat binding factor 1 (TRF1)-interacting nuclear factor 2 (TIN2). We identified by whole-genome exome sequencing compound heterozygous mutations in four siblings affected with HHS, in the gene encoding the regulator of telomere elongation helicase 1 (RTEL1). Rtel1 was identified in mouse by its genetic association with telomere length. However, its mechanism of action and whether it regulates telomere length in human remained unknown. Lymphoblastoid cell lines obtained from a patient and from the healthy parents carrying heterozygous RTEL1 mutations displayed telomere shortening, fragility and fusion, and growth defects in culture. Ectopic expression of WT RTEL1 suppressed the telomere shortening and growth defect, confirming the causal role of the RTEL1 mutations in HHS and demonstrating the essential function of human RTEL1 in telomere protection and elongation. Finally, we show that human RTEL1 interacts with the shelterin protein TRF1, providing a potential recruitment mechanism of RTEL1 to telomeres. dyskeratosis congenita | genomic instability | aging | telomeropathies H uman telomeres are composed of tandem TTAGGG DNA repeats, ending with an essential single-stranded 3′-overhang (reviewed in refs. 1 and 2). This overhang can be elongated by the enzyme telomerase to make up for losses caused by incomplete DNA replication and degradation. The expression of the telomerase reverse-transcriptase subunit (hTERT) is suppressed in most human somatic tissues; consequently, telomeres gradually shorten with each cell division. Critically short telomeres activate the DNA damage response (DDR) and cause cell-cycle arrest or apoptosis. Thus, telomere length and integrity control cellular lifespan and provide a tumor-suppressing mechanism (3). Shelterin, a complex of six core proteins, assembles at mammalian telomeres to suppress DDR and regulate telomere length (4, 5). Shelterin was suggested to facilitate the formation of a telomere (T)-loop, via invasion of double-stranded telomeric DNA by the 3′ overhang, where it is inaccessible to DDR factors and to telomerase.Dyskeratosis congenita (DC) and its severe form HoyeraalHreidarsson syndrome (HHS) are hereditary disorders associated with severely shortened telomeres and diverse clinical symptoms (6-8). The major cause of death in DC and HHS is bone marrow failure, but mortality from cancer and pulmonary fibrosis also occurs at frequencies above normal. Mu...
Placing regulatory proteins into different multiprotein complexes should modify key cellular processes. Here, we show that the transcription repressor Daxx and the SWI/SNF protein ATRX are both associated with two intranuclear domains: ND10/PML bodies and heterochromatin. The accumulation of ATRX at nuclear domain 10 (ND10) was mediated by its interaction with the N-terminus of Daxx. Binding of this complex to ND10 was facilitated by the interaction of the Daxx C-terminus with SUMOylated promyelocytic leukemia protein (PML). Although ATRX was present at heterochromatin during the entire cell cycle, Daxx was actively recruited to this domain at the end of S-phase. The FACT-complex member structure-specific recognition protein 1 (SSRP1) accumulated at heterochromatin simultaneously with Daxx and accumulation of both proteins depended on ATRX phosphorylation. Both Daxx and SSRP1 were released from heterochromatin early in G2 phase and Daxx was recruited back to ND10, indicating that both proteins localize to heterochromatin during a very short temporal window of the cell cycle. ATRX seems to assemble a repression multiprotein complex including Daxx and SSRP1 at heterochromatin during a specific stage of the cell cycle, whereas Daxx functions as an adapter for ATRX accumulation at ND10. A potential functional consequence of Daxx accumulation at heterochromatin was found in the S- to G2-phase transition. In Daxx–/– cells, S-phase was accelerated and the propensity to form double nuclei was increased, functional changes that could be rescued by Daxx reconstitution and that might be the basis for the developmental problems observed in Daxx knockout animals.
in normal cells. This result strongly suggests that pp71 and Daxx are essential for HCMV transcription at ND10. Lack of Daxx had the effect of reducing the infection rate. We conclude that the tegument transactivator pp71 facilitates viral genome deposition and transcription at ND10, possibly priming HCMV for more efficient productive infection.Nuclear domains 10 (ND10), also called PML nuclear bodies or PML oncogenic domains (PODs), represent intranuclear accumulations of several proteins, including the transcription repressors PML, Sp100, HP1, and Daxx. Within the highly specialized intranuclear architecture, ND10 presumably act as nuclear depots to maintain the homeostatic balance through controlled recruitment and release of proteins (reviewed in references 24 and 27). PML is the key component for ND10 maintenance and is responsible for the recruitment of other proteins to ND10. Daxx is recruited to ND10 from condensed chromatin through interaction with PML modified by a small ubiquitin-like modifier (SUMO-1) (15). Human Daxx was originally discovered as a DNA-binding protein (17) and has been reported to be involved in several cellular processes, including apoptosis, transcription regulation, and embryo development (reviewed in reference 26). The growing list of Daxx-interacting partners suggests that Daxx acts as a protein modulator in numerous cellular activities, while its accumulation at ND10 appears to regulate the availability of soluble Daxx for these processes.At least three ND10 proteins, PML, Sp100, and Daxx, are upregulated by interferon (7,9,10,33), suggesting the potential involvement of ND10 in the antiviral cellular response. Indeed, studies have demonstrated that several DNA viruses start their synthetic processes in the immediate vicinity of ND10 (reviewed in reference 23). Input viral DNA accumulates at ND10, followed by transcription and replication juxtaposed to ND10. The structure of ND10 becomes modified in a virus-specific manner through the action of immediate-early (IE) proteins. Thus, human cytomegalovirus (HCMV) forms a highly dynamic immediate transcript environment (ITE) during the IE stage of infection as it begins transcription juxtaposed to ND10 (16). The HCMV IE1 protein accumulates at ND10 and eventually disperses the structure (1, 18, 34), possibly through direct interaction with PML (1), while the IE2 protein accumulates juxtaposed to a subpopulation of ND10 where HCMV starts transcription, thus providing an ITE marker (16). This high spatial-temporal correlation suggests that ND10 functionally influence viral infection, although the reasons for this relationship and the consequences for virus and cell remain unclear. To further understand the early association between ND10 and viruses, we examined the processes that occur before the initiation of viral transcription, focusing on the association of HCMV tegument transactivators with ND10.During infection, the viral envelope fuses with the cell membrane, delivering tegument proteins located between the membrane envelope an...
Loss of the histone H3.3‐specific chaperone component ATRX or its partner DAXX frequently occurs in human cancers that employ alternative lengthening of telomeres (ALT) for chromosomal end protection, yet the underlying mechanism remains unclear. Here, we report that ATRX/DAXX does not serve as an immediate repressive switch for ALT. Instead, ATRX or DAXX depletion gradually induces telomere DNA replication dysfunction that activates not only homology‐directed DNA repair responses but also cell cycle checkpoint control. Mechanistically, we demonstrate that this process is contingent on ATRX/DAXX histone chaperone function, independently of telomere length. Combined ATAC‐seq and telomere chromatin immunoprecipitation studies reveal that ATRX loss provokes progressive telomere decondensation that culminates in the inception of persistent telomere replication dysfunction. We further show that endogenous telomerase activity cannot overcome telomere dysfunction induced by ATRX loss, leaving telomere repair‐based ALT as the only viable mechanism for telomere maintenance during immortalization. Together, these findings implicate ALT activation as an adaptive response to ATRX/DAXX loss‐induced telomere replication dysfunction.
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