Exposure to galactic cosmic radiation compromises DNA repair and increases the potential for oncogenic chromosomal rearrangement in bronchial epithelial cells.

Participants in deep space missions face protracted exposure to galactic cosmic radiation (GCR). In this setting, lung cancer is a significant component of the overall risk of radiation-exposure induced death. Here we investigate persistent effects of GCR exposure on DNA repair capacity in lung-derived epithelial cells, using an enzyme-stimulated chromosomal rearrangement as an endpoint. Replicate cell cultures were irradiated with energetic 48Ti ions (a GCR component) or reference γ-rays. After a six-day recovery, they were challenged by expression of a Cas9/sgRNA pair that creates double-strand breaks simultaneously in the EML4 and ALK loci, misjoining of which creates an EML4-ALK fusion oncogene. Misjoining was significantly elevated in 48Ti-irradiated populations, relative to the baseline rate in mock-irradiated controls. The effect was not seen in γ-ray irradiated populations exposed to equal or higher radiation doses. Sequence analysis of the EML4-ALK joints from 48Ti-irradiated cultures showed that they were far more likely to contain deletions, sometimes flanked by short microhomologies, than equivalent samples from mock-irradiated cultures, consistent with a shift toward error-prone alternative nonhomologous end joining repair. Results suggest a potential mechanism by which a persistent physiological effect of GCR exposure may increase lung cancer risk.

Galactic Cosmic Radiation Induces Persistent Epigenome Alterations Relevant to Human Lung Cancer.

Human deep space and planetary travel is limited by uncertainties regarding the health risks associated with exposure to galactic cosmic radiation (GCR), and in particular the high linear energy transfer (LET), heavy ion component. Here we assessed the impact of two high-LET ions 56Fe and 28Si, and low-LET X rays on genome-wide methylation patterns in human bronchial epithelial cells. We found that all three radiation types induced rapid and stable changes in DNA methylation but at distinct subsets of CpG sites affecting different chromatin compartments. The 56Fe ions induced mostly hypermethylation, and primarily affected sites in open chromatin regions including enhancers, promoters and the edges ("shores") of CpG islands. The 28Si ion-exposure had mixed effects, inducing both hyper and hypomethylation and affecting sites in more repressed heterochromatic environments, whereas X rays induced mostly hypomethylation, primarily at sites in gene bodies and intergenic regions. Significantly, the methylation status of 56Fe ion sensitive sites, but not those affected by X ray or 28Si ions, discriminated tumor from normal tissue for human lung adenocarcinomas and squamous cell carcinomas. Thus, high-LET radiation exposure leaves a lasting imprint on the epigenome, and affects sites relevant to human lung cancer. These methylation signatures may prove useful in monitoring the cumulative biological impact and associated cancer risks encountered by astronauts in deep space.

Understanding cancer development processes after HZE-particle exposure: roles of ROS, DNA damage repair and inflammation.

During space travel astronauts are exposed to a variety of radiations, including galactic cosmic rays composed of high-energy protons and high-energy charged (HZE) nuclei, and solar particle events containing low- to medium-energy protons. Risks from these exposures include carcinogenesis, central nervous system damage and degenerative tissue effects. Currently, career radiation limits are based on estimates of fatal cancer risks calculated using a model that incorporates human epidemiological data from exposed populations, estimates of relative biological effectiveness and dose-response data from relevant mammalian experimental models. A major goal of space radiation risk assessment is to link mechanistic data from biological studies at NASA Space Radiation Laboratory and other particle accelerators with risk models. Early phenotypes of HZE exposure, such as the induction of reactive oxygen species, DNA damage signaling and inflammation, are sensitive to HZE damage complexity. This review summarizes our current understanding of critical areas within the DNA damage and oxidative stress arena and provides insight into their mechanistic interdependence and their usefulness in accurately modeling cancer and other risks in astronauts exposed to space radiation. Our ultimate goals are to examine potential links and crosstalk between early response modules activated by charged particle exposure, to identify critical areas that require further research and to use these data to reduced uncertainties in modeling cancer risk for astronauts. A clearer understanding of the links between early mechanistic aspects of high-LET response and later surrogate cancer end points could reveal key nodes that can be therapeutically targeted to mitigate the health effects from charged particle exposures.

Gene amplification and associated loss of 5' regulatory sequences of CoAA in human cancers.

CoAA is an RRM-containing transcriptional coactivator that stimulates transcriptional activation and regulates alternative splicing. We show that the CoAA gene is amplified at the chromosome 11q13 locus in a subset of primary human cancers including non-small cell lung carcinoma, squamous cell skin carcinoma and lymphoma. Analysis of 42 primary tumors suggests that CoAA amplifies independently from the CCND1 locus. Detailed mapping of three CoAA amplicons reveals that the amplified CoAA gene is consistently located at the 5' boundaries of the amplicons. The CoAA coding and basal promoter sequences are retained within the amplicons but upstream silencing sequences are lost. CoAA protein is overexpressed in tumors containing the amplified CoAA gene. RNA dot blot analysis of 100 cases of primary tumors suggests elevated CoAA mRNA expression. CoAA positively regulates its own basal promoter in transfection assays. Thus, gene amplification, loss of silencing sequence and positive feedback regulation may lead to drastic upregulation of CoAA protein. CoAA has transforming activities when tested in soft agar assays, and CoAA is homologous to oncoproteins EWS and TLS, which regulate alternative splicing. These data imply that CoAA may share a similar oncogenic mechanism with oncogene EWS and that CoAA deregulation may alter the alternative splicing of target genes.

Autoantibodies against DNA double-strand break repair proteins.

Autoantibodies against cellular components are commonly present in sera from patients with systemic rheumatic diseases and may play an important role in pathogenesis. The Ku protein was recognized 20 years ago as a major target of autoantibodies in a subset of Japanese patients with scleroderma-polymyositis overlap syndrome, and anti-Ku antibodies have since been shown to occur in 10-20% of patients with these and other systemic rheumatic diseases, including systemic lupus erythematosus. Ku functions physiologically in the repair of DNA double-strand breaks, where it carries out the initial recognition of damaged DNA ends. The three dimensional structure of the Ku-DNA complex has recently been solved, and helps illuminate the relationship between the autoimmune epitopes and other features of the protein. In addition to Ku, three other polypeptides in the same DNA repair pathway have more recently been identified as autoantigens: the DNA-dependent protein kinase catalytic subunit, DNA ligase IV, and XRCC4. Two hypotheses have been invoked to explain the ability of these proteins to elicit an autoimmune response in susceptible individuals. One is that DNA damage induces formation of nucleoprotein complexes that present novel composite or conformational epitopes. The other is that cleavage of these proteins by caspases or Granzyme B leads to presentation of immunocryptic peptides capable of stimulating autoreactive T lymphocytes. In the case of DNA double-strand break repair proteins, there is evidence that both of these mechanisms may be at work. Because of their role in the maintenance of genome stability, DNA double-strand break repair proteins have been the subject of intense study, and a wealth of new structural, biochemical and functional information makes them excellent models for investigation of the humoral autoimmune response.

DNA ligase IV and XRCC4 form a stable mixed tetramer that functions synergistically with other repair factors in a cell-free end-joining system.

Repair of DNA double-strand breaks in mammalian cells occurs via a direct nonhomologous end-joining pathway. Although this pathway can be studied in vivo and in crude cell-free systems, a deeper understanding of the mechanism requires reconstitution with purified enzymes. We have expressed and purified a complex of two proteins that are critical for double-strand break repair, DNA ligase IV (DNL IV) and XRCC4. The complex is homogeneous, with a molecular mass of about 300,000 Da, suggestive of a mixed tetramer containing two copies of each polypeptide. The presence of multiple copies of DNL IV was confirmed in an experiment where different epitope-tagged forms of DNL IV were recovered simultaneously in the same complex. Cross-linking suggests that an XRCC4.XRCC4 dimer interface forms the core of the tetramer, and that the DNL IV polypeptides are in contact with XRCC4 but not with one another. Purified DNL IV.XRCC4 complex functioned synergistically with Ku protein, the DNA-dependent protein kinase catalytic subunit, and other repair factors in a cell-free end-joining assay. We suggest that a dyad-symmetric DNL IV.XRCC4 tetramer bridges the two ends of the broken DNA and catalyzes the coordinate ligation of the two DNA strands.

Human RNA helicase A is a lupus autoantigen that is cleaved during apoptosis.

Proteolytic cleavage by caspases is the central event in cells undergoing apoptosis. Cleaved proteins are often targeted by autoantibodies, suggesting that the cleavage of self Ags enhances immunogenicity and is prone to induce an autoimmune response. We found autoantibodies that immunoprecipitated a 140-kDa RNA-associated protein, provisionally designated Pa, in 11 of 350 patient sera that were positive for antinuclear Abs in an immunofluorescence test. The Pa protein gave rise to three fragments with m.w. ranging from 120-130 kDa during anti-Fas-activated apoptosis. Pure caspase-3 cleaved the Pa protein into a 130-kDa fragment corresponding to the largest of these three products. Peptide sequence analysis of a tryptic digest from immunoaffinity-purified Pa showed 100% identity to human RNA helicase A (RHA). The identity of Pa with RHA was further confirmed by immunoblotting with rabbit anti-RHA Ab using anti-Pa immunoprecipitates as substrates. All 10 anti-RHA-positive patients who were clinically analyzed were diagnosed as having systemic lupus erythematosus, and 7 of them had lupus nephritis. RHA is a multifunctional protein with roles in cellular RNA synthesis and processing. Inactivation of RHA by cleavage may be an important part of the process leading to programmed cell death. The cleaved RHA fragments that are produced during apoptosis may trigger an autoimmune response in systemic lupus erythematosus.

Identification of a human T-cell leukemia virus type I tax peptide in contact with DNA.

The human T-cell leukemia virus Tax protein directs binding of a host factor, cAMP response element binding protein, to an extended recognition sequence in the proviral promoter. Prior cross-linking experiments have revealed that Tax makes restricted contact with this DNA at two symmetric positions, 14 nucleotides apart on opposite strands of the DNA. Tax lacks a conventional DNA binding domain, and the sequences in Tax that are in contact with DNA have not been previously identified. Analysis of cross-linked peptides now shows that the contact occurs between Tax residues 89 and 110, corresponding to a protease-sensitive linker joining two protein structural domains. The linker assumes a protease-resistant conformation in the cross-linked complex. Point mutations within the linker prevent cross-linking and interfere with Tax function. These data suggest that entry of Tax into the ternary complex may be coupled to folding of an unstructured protein domain, which then makes base-specific contacts with DNA.

Human autoantibodies recognizing a native macromolecular structure composed of Sm core proteins in U small nuclear RNP particles.

OBJECTIVE: Monoclonal antibody (mAb) F78 recognizes a heat-labile particle composed of Sm core proteins designated F78P. The objective of this study was to identify human autoantibodies recognizing the conformational structure of F78P. METHODS: Immunoblots using HeLa cell extracts without heating prior to sodium dodecyl sulfate-polyacrylamide gel electrophoresis were used to identify autoantibodies recognizing F78P. To confirm reactivities with F78P, immunoprecipitates of mAb F78 were used as a substrate for immunoblots. To identify reactivities against the F78P structure in classic anti-Sm-positive sera, autoantibodies to individual Sm core proteins were absorbed with purified U1 small nuclear RNP before immunoblotting. RESULTS: We identified 2 sera that, like F78, recognized only F78P and not its component polypeptides. When classic anti-Sm antibodies were preabsorbed, the presence of F78-like, particle-specific antibodies was revealed in all of the anti-Sm-positive sera tested. CONCLUSION: Autoantibodies against the F78P structure were commonly present in sera from patients with systemic rheumatic diseases, often in combination with4=1998 M autoantibodies.

Specific regions of contact between human T-cell leukemia virus type I Tax protein and DNA identified by photocross-linking.

The human T-cell leukemia virus type I Tax protein forms a ternary complex on DNA in association with a host factor, the cyclic AMP response element-binding protein (CREB). An understanding of the precise geometry of this complex has been elusive. We have used photocross-linking to investigate Tax-DNA contacts. Our data show that Tax contacts the DNA at two symmetric positions 14 nucleotides apart on either side of the Tax responsive element. The presence of symmetric, widely separated regions of contact suggests that at least two molecules of Tax are present in the complex. Mapping the contacts onto a three-dimensional model of the CREB-DNA binary complex shows that they lie on the same face of the DNA near the regions where the N termini of the CREB bZIP domains enter the major groove. This location correlates well with previous evidence that CREB amino acid residues immediately N-terminal to the bZIP domain are crucial for the formation of the ternary complex. The limited number of cross-links observed suggests that contacts are primarily with the phosphate backbone and does not support the idea that a major structural element of the Tax protein inserts into the major or minor grooves of the DNA.

Characterization of the RNA binding properties of Ku protein.

Ku protein, a heterodimer of 70 and 83 kDa polypeptides, is the regulatory component of the DNA-dependent protein kinase (DNA-PK). Ku protein binds to DNA ends and is essential for DNA double-strand break repair and V(D)J recombination. Although there is some evidence that Ku protein also binds RNA, its RNA binding properties have not been systematically explored. In the present study, Ku-binding RNAs were identified using systematic evolution of ligands by exponential enrichment (SELEX) technology. These RNAs were assigned to three classes based on common sequence motifs. Most of the selected RNAs bound to Ku protein with a Kd < or = 2 nM, comparable to the affinity of DNA fragments for Ku protein under similar conditions. Many of the RNAs inhibited DNA-PK activity by competing with DNA for a common binding site in Ku protein. None of several RNAs that were tested activated DNA-PK in the absence of DNA. The identification of diverse RNAs that bind avidly to Ku protein is consistent with the idea that natural RNAs may serve as modulators of DNA-PK activity. Moreover, the RNAs identified in this study may have utility as tools for experimental manipulation of DNA double-strand break repair activity in cells and cell extracts.

Ku proteins join DNA fragments as shown by atomic force microscopy.

The binding of the Ku protein to DNA was investigated using the atomic force microscope. Ku was found to bind predominantly to the ends of double-stranded DNA. Experiments with plasmid DNA revealed that Ku does not bind to circular plasmids but does bind to plasmids that have been linearized by treatment with ionizing radiation. The binding of Ku to poly(dG-dC) x poly(dG-dC) polynucleotides and to a 400-bp DNA EcoRI fragment resulted in a shift in the fragment size distribution to include longer fragments, with internally binding Ku. Furthermore, we observed images consistent with fragments joined together by Ku, showing an interaction with two ends of DNA. These observations suggest that Ku may play a role in physically orienting DNA for ligation by binding the ends of adjacent DNA molecules.

The DNA-dependent protein kinase catalytic subunit (p460) is cleaved during Fas-mediated apoptosis in Jurkat cells.

The DNA-dependent protein kinase (DNA-PK) is a serine/threonine kinase linked to DNA repair and V(D)J recombination. It is composed of a 460-kDa catalytic subunit (DNA-PKcs) and a 70/86-kDa heterodimeric regulatory component that is identical with the human autoantigen Ku. The regulatory subunit targets the catalytic subunit to the free ends of dsDNA breaks. Since apoptosis is associated with internucleosomal chromatin fragmentation and creation of dsDNA breaks, we examined whether the biochemical amounts of either DNA-PKcs or Ku changed during apoptosis mediated by the cell surface receptor Fas. We found that the catalytic subunit was cleaved into several smaller polypeptides early in apoptosis. In contrast to DNA-PKcs, Ku was neither cleaved nor decreased in amount during apoptosis. We then extended our in vivo results to a cellfree system. Cytosolic extracts derived from apoptotic cells were able to cleave DNA-PKcs into polypeptides of sizes identical with those seen in vivo, and this cleavage was inhibited by the cysteine protease inhibitors iodoacetamide and N-ethylmaleimide. Furthermore, DNA-PKcs was cleaved in vitro by purified apopain (CPP32), but not IL-1beta-converting enzyme. Cleavage was also inhibited by the specific tetrapeptide DEVD (amino acids 2709-2712 of the DNA-PKcs sequence), suggesting a candidate position for protease action. Finally, we found that the catalytic activity of DNA-PKcs was decreased in apoptotic cells. We conclude that DNA-PKcs is subject to selective cleavage by proteases during apoptosis. Cleavage of DNA-PKcs may represent a mechanism for regulating the function of DNA-dependent kinase during programmed cell death.

Autoantibodies to DNA-dependent protein kinase. Probes for the catalytic subunit.

DNA-dependent protein kinase (DNA-PK) is an important nuclear enzyme which consists of a catalytic subunit known as DNA-PKcs and a regulatory component identified as the Ku autoantigen. In the present study, we surveyed 312 patients in a search for this specificity. 10 sera immunoprecipitated a large polypeptide which exactly comigrated with DNA-PKcs in SDS-PAGE. Immunoblot analysis demonstrated that this polypeptide was recognizable by a rabbit antiserum specific for DNA-PKcs. Although the patient sera did not bind to biochemically purified DNA-PKcs in immunoblots or ELISA, they were able to deplete DNA-PK catalytic activity from extracts of HeLa cells in a dose-dependent manner. We conclude that these antibodies should be useful probes for studies which aim to define the role of DNA-PK in cells. Since six sera simultaneously contained antibodies to the Ku protein, these studies suggest that relatively intact forms of DNA-PK complex act as autoantigenic particles in selected patients.

Loss of the catalytic subunit of the DNA-dependent protein kinase in DNA double-strand-break-repair mutant mammalian cells.

The DNA-dependent protein kinase (DNA-PK) consists of three polypeptide components: Ku-70, Ku-80, and an approximately 350-kDa catalytic subunit (p350). The gene encoding the Ku-80 subunit is identical to the x-ray-sensitive group 5 complementing gene XRCC5. Expression of the Ku-80 cDNA rescues both DNA double-strand break (DSB) repair and V(D)J recombination in group 5 mutant cells. The involvement of Ku-80 in these processes suggests that the underlying defect in these mutant cells may be disruption of the DNA-PK holoenzyme. In this report we show that the p350 kinase subunit is deleted in cells derived from the severe combined immunodeficiency mouse and in the Chinese hamster ovary cell line V-3, both of which are defective in DSB repair and V(D)J recombination. A centromeric fragment of human chromosome 8 that complements the scid defect also restores p350 protein expression and rescues in vitro DNA-PK activity. These data suggest the scid gene may encode the p350 protein or regulate its expression and are consistent with a model whereby DNA-PK is a critical component of the DSB-repair pathway.

Quantitative studies of the effect of HTLV-I Tax protein on CREB protein--DNA binding.

The human T-cell leukemia virus type I (HTLV-I) Tax protein increases the DNA binding activity of a number of different host cell transcription factors, including the cyclic AMP response element binding protein (CREB). We have performed quantitative studies of CREB binding in the presence and absence of Tax in an attempt to gain insight into the mechanism of the Tax effect. Enhancement of binding occurred over a wide range of CREB concentrations, but sharply increased at the lowest concentrations tested. The data are best explained by a two-step binding model where Tax changes the apparent equilibrium constants for both a CREB-CREB dimerization step and a (CREB)2-DNA binding step. We used the model to perform a quantitative analysis of the binding of CREB to DNA that had been mutated at positions flanking the core CREB recognition site. Results suggest that there are altered or more extensive DNA-protein contacts at these positions in the presence of Tax. We also used the model to analyze differences in the interaction of Tax with nonphosphorylated and protein kinase A-phosphorylated CREB protein. There was no significant change in the behavior of CREB upon phosphorylation.

Transactivation by the human T-cell leukemia virus Tax protein is mediated through enhanced binding of activating transcription factor-2 (ATF-2) ATF-2 response and cAMP element-binding protein (CREB).

The human T-cell leukemia virus type I (HTLV-I)-encoded transcriptional activator protein Tax is strongly implicated in HTLV-I pathogenesis. Tax regulates HTLV-I gene expression through three 21-base pair (bp) repeat enhancer elements located in the transcriptional control region of the virus. Tax does not bind these elements directly, but mediates transactivation through the cellular transcription factors that recognize a cAMP response element (CRE)-like sequence centered within each of the 21-bp repeats. In this report, we identify activating transcription factor-2 (ATF-2) and CRE-binding protein (CREB) as the principal T-cell proteins that bind the three 21-bp repeats in vitro. Purified Tax protein augments the level of RNA synthesis induced by ATF-2 and CREB in a cell-free transcription assay, providing evidence that Tax cooperates with these cellular proteins to activate HTLV-I transcription. Furthermore, Tax dramatically increases the binding of both the T-cell-derived and recombinant forms of ATF-2 and CREB to each of the 21-bp repeats. The target sequences for this enhancement reside within the DNA binding/dimerization domains of these proteins. These data suggest that Tax transactivates HTLV-I gene expression by increasing the number of bound ATF-2 and CREB molecules at the viral promoter.

Purification and characterization of a template-associated protein kinase that phosphorylates RNA polymerase II.

We have recently shown that a template-associated protein kinase, which phosphorylates the carboxyl-terminal domain (CTD) of RNA polymerase II, is a two-component system. We describe here the purification of these two components to apparent homogeneity from human (HeLa) cell nuclear extract. Kinase component A has a 340-kDa native molecular mass, consists of a single large polypeptide, and contains the kinase active site. Kinase component B, which is identical to the Ku autoantigen, has a 180-kDa native molecular mass, and consists of apparently equimolar 67- and 83-kDa polypeptides. Component B stimulates the activity of component A, and under some conditions, confers DNA dependence on the reaction. The purified kinase converts the CTD to the multiply phosphorylated CTD0 form. Conversion occurs processively, and this processivity is an inherent property of component A. The in vitro phosphorylated CTD0 form contains approximately equimolar phosphoserine and phosphothreonine, but no detectable phosphotyrosine.

Incidence of BK virus and JC virus viruria in human immunodeficiency virus-infected and -uninfected subjects.

BK virus (BKV) and JC virus (JCV) are present within the renal system of most adults. Reactivation may be linked to immunodeficiency, since many of the extant virus strains have been isolated from urine or kidney tissue of patients who were receiving immunosuppressive therapy or who had disorders of the immune system. To more critically evaluate the relationship between immunodeficiency and viruria, urine samples from individuals infected with human immunodeficiency virus (HIV) with various degrees of immunodeficiency were screened for the presence of viral DNA. JCV viruria occurred in 24%-27% of immunocompetent control subjects and was not increased with immunodeficiency. By contrast, there were both qualitative and quantitative changes in BKV viruria in immunodeficient subjects. The incidence of BKV viruria was increased, and some immunodeficient subjects shed BKV at levels up to 3000 times greater than levels shed by any of the nonimmunodeficient controls. DNA sequence rearrangements in the viral regulatory region did not appear to be required for shedding of virus, although they were present in approximately 20% of samples.

Ku autoantigen is the regulatory component of a template-associated protein kinase that phosphorylates RNA polymerase II.

The carboxyl-terminal domain of RNA polymerase II contains a tandemly repeated heptapeptide sequence. Previous work has shown that this sequence is phosphorylated at multiple sites by a template-associated protein kinase, in a reaction that is closely associated with the initiation of RNA synthesis. We have purified this kinase to apparent homogeneity from human (HeLa) cells. The purified kinase phosphorylates native RNA polymerase II only in the presence of DNA and the general transcription factors TFIID (TBP), TFIIB, and TFIIF. Two kinase components are required for full activity: a catalytic component and a DNA-binding regulatory component. The regulatory component has been identified as Ku autoantigen, based on the molecular weights of its component polypeptides, its DNA-binding properties, and its reactivity with anti-Ku monoclonal antibodies. The Ku autoantigen recruits the catalytic component of the kinase to the template. Ku autoantigen has been previously proposed to interact with DNA by a characteristic bind-and-slide mechanism. This mode of interaction may provide a mechanism for targeting the kinase to the transcription complex and other DNA-bound substrates.