Chromatin reorganization plays an important role in DNA repair, apoptosis, and cell cycle checkpoints. Among proteins involved in chromatin reorganization, TIP60 histone acetyltransferase has been shown to play a role in DNA repair and apoptosis. However, how TIP60 regulates chromatin reorganization in the response of human cells to DNA damage is largely unknown. Here, we show that ionizing irradiation induces TIP60 acetylation of histone H2AX, a variant form of H2A known to be phosphorylated following DNA damage. Furthermore, TIP60 regulates the ubiquitination of H2AX via the ubiquitin-conjugating enzyme UBC13, which is induced by DNA damage. This ubiquitination of H2AX requires its prior acetylation. We also demonstrate that acetylation-dependent ubiquitination by the TIP60-UBC13 complex leads to the release of H2AX from damaged chromatin. We conclude that the sequential acetylation and ubiquitination of H2AX by TIP60-UBC13 promote enhanced histone dynamics, which in turn stimulate a DNA damage response.Chromatin reorganization by histone modification and mobilization plays a crucial role in DNA metabolism, including replication, transcription, and repair. It appears that histone modification and mobilization can reorganize chromatin to allow DNA repair machinery to access damaged chromosomal DNA (11,29,52,56,57).H2AX is a histone variant that differs from H2A at various amino acid residues along the entire protein and in its Cterminal extensions. H2AX is phosphorylated after the induction of DNA double-strand breaks (DSBs), and the phosphorylated H2AX (␥-H2AX) participates in focus formation at sites of DNA damage. After induction of DSBs, the MRN complex (MRE11, RAD50, and NBS1) binds to broken DNA ends and recruits active ATM, ATR, and/or DNA protein kinase, resulting in the initial phosphorylation of H2AX (32,38,40). MDC1 then associates with ␥-H2AX and recruits additional activated ATM to the sites of DSBs (23,46). This positive feedback loop leads to the expansion of the ␥-H2AX region surrounding DSBs and provides docking sites for many DNA damage and repair proteins, including the MRN complex, 53BP1, and BRCA1 (5, 6, 46). ␥-H2AX plays a role in the accumulation but not in the initial recruitment of repair factors such as the MRN complex, 53BP1, and BRCA1 (10, 63). Therefore, modifications of H2AX other than phosphorylation could play a role in the initial step of the DNA damage response.Until recently, the biological significance of ubiquitination in the DNA damage response has been unclear. H2B ubiquitination regulates the damage checkpoint response (15). H2A is ubiquitinated during the response to UV-induced DNA damage (8). UV-induced DNA damage also causes the ubiquitination of histones H3 and H4, resulting in their release from chromatin (60). Interestingly, ubiquitin-conjugated proteins appear to be accumulated at sites of DSBs, forming nuclear foci like ␥-H2AX (34). These findings raise the possibility that histone ubiquitination is also involved in the reorganization of chromatin in response to D...
Significance Cell survival after DNA damage relies on DNA repair, the abrogation of which causes genomic instability and development of cancer. DNA double-strand breaks are lesions induced by ionizing radiation (IR) and can be efficiently repaired by DNA homologous recombination, a system that requires RAD51 recombinase (RAD51). Here we show that overexpression of miR-155 in human breast cancer cells reduces the levels of RAD51 and affects the cellular response to IR. High miR-155 levels were associated with lower RAD51 expression and with better overall survival of patients in a large series of triple-negative breast cancers. Testing triple-negative breast cancer patients for miR-155 expression may be a useful prognostic tool to identify who will benefit from an IR-based therapeutic approach.
Glioblastoma (GBM) is the most common and aggressive histologic subtype of brain cancer with poor outcomes and limited treatment options. Here we report the selective overexpression of the protein arginine methyltransferase PRMT5 as a novel candidate theranostic target in this disease. PRMT5 silences the transcription of regulatory genes by catalyzing symmetric di-methylation of arginine residues on histone tails. PRMT5 overexpression in patient-derived primary tumors and cell lines correlated with cell line growth rate and inversely with overall patient survival. Genetic attenuation of PRMT5 led to cell cycle arrest, apoptosis and loss of cell migratory activity. Cell death was p53-independent but caspase-dependent and enhanced with temozolomide, a chemotherapeutic agent used as a present standard of care. Global gene profiling and chromatin immunoprecipitation identified the tumor suppressor ST7 as a key gene silenced by PRMT5. Diminished ST7 expression was associated with reduced patient survival. PRMT5 attenuation limited PRMT5 recruitment to the ST7 promoter, led to restored expression of ST7 and cell growth inhibition. Lastly, PRMT5 attenuation enhanced GBM cell survival in a mouse xenograft model of aggressive GBM. Together, our findings defined PRMT5 as a candidate prognostic factor and therapeutic target in GBM, offering a preclinical justification for targeting PRMT5-driven oncogenic pathways in this deadly disease.
Exposure to ionizing radiation through environmental, occupational or a nuclear reactor accident such as the recent Fukushima Daiichi incident often results in major consequences to human health. The injury caused by radiation can manifest as acute radiation syndromes within weeks in organs with proliferating cells such as hematopoietic and gastrointestinal systems. Cancers, fibrosis and degenerative diseases are also reported in organs with differentiated cells, months or years later. Studies conducted on atom bomb survivors, nuclear reactor workers and animal models have shown a direct correlation of these effects with the absorbed dose. Physical dosimeters and the available radio-responsive biologics in body fluids, whose responses are rather indirect, have limitations to accurately evaluate the extent of post exposure damage. We have used an amplification-free, hybridization based quantitative assay utilizing the nCounter multiplex platform developed by nanoString Technologies to compare the levels of over 600 miRNAs in serum from mice irradiated at a range of 1 to 12 Gy at 24 and 48 hr time points. Development of a novel normalization strategy using multiple spike-in oligonucleotides allowed accurate measurement of radiation dose and time dependent changes in serum miRNAs. The response of several evolutionarily conserved miRNAs abundant in serum, were found to be robust and sensitive in the dose range relevant for medical triage and in patients who receive total body radiation as preparative regimen for bone marrow transplantation. Notably, miRNA-150, abundant in lymphocytes, exhibited a dose and time dependent decrease in serum, which we propose as a sensitive marker indicative of lymphocyte depletion and bone marrow damage. Our study has identified several markers useful for evaluation of an individual’s response by minimally invasive methods, relevant to triage in case of a radiation accident and evaluation of toxicity and response during and after therapeutic radiation.
Nuclear factor (NF)-jB is a positive regulator of tumour development and progression, but how it functions in normal cells leading to oncogenesis is not clear. As cellular senescence has proven to be an intrinsic tumour suppressor mechanism that cells must overcome to establish deregulated growth, we used primary fibroblasts to follow NF-jB function in cells transitioning from senescence to subsequent immortalization. Our findings show that RelA/p65 À/À murine fibroblasts immortalize at considerably faster rates than RelA/p65 þ / þ cells. The ability of RelA/p65 À/À fibroblasts to escape senescence earlier is due to their genomic instability, characterized by high frequencies of DNA mutations, gene deletions and gross chromosomal translocations. This increase in genomic instability is closely related to a compromised DNA repair that occurs in both murine RelA/p65 À/À fibroblasts and tissues. Significantly, these results can also be duplicated in human fibroblasts lacking NF-jB. Altogether, our findings present a fresh perspective on the role of NF-jB as a tumour suppressor, which acts in pre-neoplastic cells to maintain cellular senescence by promoting DNA repair and genomic stability.
To learn more about the structure of the DNA terminus at Tetrahymena thermophila telomeres, we have devised a ligation-mediated primer extension protocol to accurately measure the length of the G-strand overhang. We show that overhang length and the identity of the 3¢-terminal nucleotide are tightly regulated. The majority of overhangs terminate in the sequence 5¢-TTGGGGT and >80% are either 14±15 or 20±21 nucleotides in length. No signi®cant changes in overhang length were detected as cells traversed the cell cycle. However, changes in length distribution were observed when cells exited the cell cycle, indicating an altered balance between DNA synthesis and degradation or end protection. We also provide evidence that rDNA molecules have overhangs on both telomeres. Full-length rDNA could be cloned by a strategy that depends on overhangs being present at both ends. Moreover, analysis of leading strand telomeres revealed that a signi®cant fraction have overhangs >5 nucleotides. Our results indicate that generation of the terminal telomeric DNA structure is highly regulated and requires several distinct DNA-processing events.
The POT1/TEBP telomere proteins are a group of single-stranded DNA (ssDNA)-binding proteins that have long been assumed to protect the G overhang on the telomeric 3 strand. We have found that the Tetrahymena thermophila genome contains two POT1 gene homologs, POT1a and POT1b. The POT1a gene is essential, but POT1b is not. We have generated a conditional POT1a cell line and shown that POT1a depletion results in a monster cell phenotype and growth arrest. However, G-overhang structure is essentially unchanged, indicating that POT1a is not required for overhang protection. In contrast, POT1a is required for telomere length regulation. After POT1a depletion, most telomeres elongate by 400 to 500 bp, but some increase by up to 10 kb. This elongation occurs in the absence of further cell division. The growth arrest caused by POT1a depletion can be reversed by reexpression of POT1a or addition of caffeine. Thus, POT1a is required to prevent a cell cycle checkpoint that is most likely mediated by ATM or ATR (ATM and ATR are protein kinases of the PI-3 protein kinase-like family). Our findings indicate that the essential function of POT1a is to prevent a catastrophic DNA damage response. This response may be activated when nontelomeric ssDNA-binding proteins bind and protect the G overhang.In order to maintain genome integrity, the telomeric DNA from cells with linear chromosomes is packaged into a protective nucleoprotein complex (10). In the absence of this complex, the telomeres are recognized as DNA damage and subject to repair by nonhomologous end joining (33). The resulting chromosome fusions lead to genome instability (36). The protective telomeric complex is composed of a series of unique telomere proteins that bind the double-stranded region of the telomeric DNA and/or the single-strand overhang on the 3Ј G-rich strand (37). Although the exact composition of the complex varies between species, vertebrates, yeasts, plants, and ciliates all use a series of structurally related proteins to protect their telomeres. The G-overhang binding proteins all bind Gstrand DNA through a conserved OB fold motif, while the double-stranded DNA-binding proteins bind via a conserved myb motif (23,37,46).In vertebrate cells, telomeres are packaged by a core complex of six proteins which function both in telomere protection and in telomere length regulation (10). This core complex (which is sometimes called shelterin) contains two doublestranded DNA-binding proteins, TRF1 and TRF2, which anchor the complex along the length of the telomere, and the TRF1/2 interaction partners Rap1, TIN2, and TPP1. The Gstrand binding protein POT1 is also a component of the complex. Although POT1 is secured into the complex through interactions with TPP1 (17, 31, 50), POT1 molecules are also thought to bind the G-strand overhang via their OB foldcontaining DNA-binding domain (45,46). Additional telomere-associated proteins include a number of DNA damage response factors (33). However, these factors appear to bind only transiently during replication of...
Here we describe the use of reverse-phase liquid chromatography mass spectrometry (RP-LC-MS) to simultaneously characterize variants and post-translationally modified isoforms for each histone. The analysis of intact proteins significantly reduces the time of sample preparation and simplifies data interpretation. LC-MS analysis and peptide mass mapping have previously been applied to identify histone proteins and to characterize their post-translational modifications. However, these studies provided limited characterization of both linker histones and core histones. The current LC-MS analysis allows for the simultaneous observation of all histone PTMs and variants (both replacement and bulk histones) without further enrichment, which will be valuable in comparative studies. Protein identities were verified by the analysis of histone H2A species using RPLC fractionation, AU-PAGE separation and nano-LC-MS/MS.
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