Antigenic determinants of the Ku (p70/p80) autoantigen are poorly conserved between species.

The Ku (p70/p80) autoantigen is a DNA-protein complex recognized by sera from certain patients with SLE and related diseases. Although human autoantibodies react with at least eight different epitopes of the human Ku complex, they had little reactivity with rodent Ku Ag on immunoblots. Small amounts of 70- and 80-kDa proteins were immunoprecipitated from murine cell extracts, however, suggesting that the Ku particle is not unique to human cells. This was confirmed by isolating cDNA clones encoding murine Ku Ag by plaque hybridization with a human p70 cDNA probe. The murine p70 cDNA clones had a deduced amino acid sequence 82.9% identical to that of human p70, and comparable amounts of murine and human p70 mRNA were detected in 3T3 and K562 cells, respectively. The poor reactivity of human autoantibodies with murine p70 was attributable to specific amino acid substitutions in an immunodominant conformational epitope located on amino acids 560-609 of human p70. Several amino acids critical for antigenicity of this region were defined by mutagenesis studies. Other conformational epitopes of Ku were also antigenically poorly conserved among species. Species-specific epitopes recognized by lupus autoantibodies are unusual but not unique to Ku. In general, poorly conserved autoepitopes have been conformational, rather than sequential, suggesting that the antigenicity of conformational epitopes may be particularly sensitive to evolutionary change.     

Epitopes of the p70 and p80 (Ku) lupus autoantigens.

High titer autoantibodies to the Ku Ag, a DNA-protein complex containing 70- and approximately 80-kDa protein subunits (p70 and p80, respectively), are found in sera of certain patients with systemic lupus erythematosus and related disorders. Autoepitopes of the Ku Ag were identified and partially characterized by expressing fragments of the p70 and p80 cDNA as fusion proteins in bacteria. Systemic lupus erythematosus sera reacted on immunoblots with at least three epitopes of p70 (amino acids 560-609, 506-535, and 115-467), and three epitopes of p80 (amino acids 682-732, 558-681, and 1-374). These six antigenic regions had distinct amino acid sequences, and were also immunologically distinct, as determined by using immunoaffinity-purified auto-antibodies to particular epitopes. Detailed mapping of the strongly antigenic region near the C terminus of p70 revealed a complex conformational or discontinuous epitope, the antigenicity of which was abolished by deleting either amino acids 560-571 or 601-609. The C terminus of p80 may also contain a discontinuous or conformational epitope(s). Although only some sera reacted with p70 or p80 on immunoblots, all sera that immunoprecipitated the native Ku complex reacted with native Ku by ELISA, and inhibited the binding of mAb directed at epitopes of native Ku. Taken together, these studies indicate that anti-Ku autoantibodies target a diversity of independent epitopes located on p70, p80, and the intact Ku complex, and that a significant portion of the autoantibodies in most patients' sera is directed against conformational/discontinuous epitopes.     

Molecular cloning and sequencing of cDNAs encoding homologues of human Ku70 and Ku80 autoantigen from Xenopus and their expression in various Xenopus tissues

We isolated cDNA clones encoding Ku70 and Ku80 homologues of Xenopus laevis from a cDNA library prepared from Xenopus oocytes. The nucleotide sequences of these Ku70 and Ku80 homologues have coding sequences of 1833 bp and a 611 aa protein, and 2178 bp and a 726 aa protein, respectively. The amino acid sequences deduced from the open reading frame of the Ku70 and Ku80 cDNA clones were highly homologous to those from Ku genes previously isolated, such as human (ca. 65% and ca. 62% identity, respectively) and mouse (ca. 65% and ca. 60%), and show a certain degree of homology to Drosophila (ca. 27% with Ku70), Caenorhabditis elegans (ca. 20% with Ku80) and Saccharomyces cerevisiae (ca. 23% and ca. 19%). Our detailed comparison of the predicted amino acid sequences among these species revealed the highly conserved octa-peptide LPFXXDIR common to both Xenopus Ku70 and Ku80 homologues in the region showing the high homology throughout the species tested. A Northern analysis using specific cDNA probes showed that Ku poly(A)+ mRNAs are expressed at high levels in Xenopus adult oocyte and testis.     

Exogenously expressed human Ku70 stabilizes Ku80 in Xenopus oocytes and induces heterologous DNA-PK catalytic activity

The Ku protein is a heterodimer composed of 70 kD (Ku70) and 80 kD (Ku80) subunits. Ku is the regulatory component of the DNA-dependent protein kinase (DNA-PK) that has a catalytic subunit of ~460 kD (DNA-PK_cs). In this study, the two polypeptides (Ku80/Ku70) of the human Ku were expressed in Xenopus oocytes in order to investigate their over-expression, sub-cellular localization, and functional interaction with the Xenopus DNA-PK_cs. In vitro-transcribed mRNAs for Ku70 and Ku80 were obtained from the respective plasmid constructs. The exogenously expressed proteins from the injected mRNAs were immunoprecipitated using a specific anti-T7 Tag antibody. The T7 Tag epitope is present in the vector at the amino-terminus and is in-frame with the Ku cDNA sequences. While injected Ku70 mRNA translated to a full-length Ku70 polypeptide that translocated to the nucleus, injected Ku80 mRNA resulted in the expression of a truncated product that was retained in the cytoplasm. Although Ku80 mRNA was stable for a period of 18 h in the oocytes post-microinjection, the protein was only stabilized when co-expressed with Ku70, suggesting that Ku80 is susceptible to proteolytic degradation when not dimerized with Ku70. Furthermore, the immunocomplex was capable of phosphorylating the DNA-PK-specific substrate thereby indicating that the holoenzyme could functionally reconstitute in vivo in the oocytes by heterologous subunits thus demonstrating evolutionary conservation of the enzyme subunit structure and function among diverse species.     

Expression and chromosome location of hamster Ku70 and Ku80

Ku proteins play an important role in DNA double-strand break (DSB) repair, chromosome maintenance, and growth regulation. To understand the fundamental characteristics of Ku proteins, we examined the electrophoretic mobility and expression of hamster Ku70 and Ku80 and determined the chromosome locations of their genes. The electrophoretic mobility of hamster Ku proteins are different from that of human Ku proteins. No significant changes in the quantity of Ku proteins were observed in CHO-K1 cells treated with 10 Gy of ionizing radiation, suggesting that both proteins are expressed constitutively in amounts adequate to repair DNA DSBs. The chromosome locations of the Ku genes were determined by direct R-banding fluorescence in situ hybridization. The Ku70 gene was localized to Syrian hamster chromosome 4qa4.1--> qa4.2 and Chinese hamster chromosome 2p3.1, and the Ku80 gene was localized to Syrian hamster chromosome 4qb5--> qb6.1 and Chinese hamster chromosome 2p3.5-->p3.6. These results provide clues to the biological functions of Ku, as well as useful information for constructing comparative chromosome maps between hamsters and other mammalian species, including human, mouse, and rat.     

Double-strand break repair by Ku70 requires heterodimerization with Ku80 and DNA binding functions.

Heterodimers of the 70 and 80 kDa Ku autoantigens (Ku70 and Ku80) activate the DNA-dependent protein kinase (DNA-PK). Mutations in any of the three subunits of this protein kinase (Ku70, Ku80 and DNA-PKcs) lead to sensitivity to ionizing radiation (IR) and to DNA double-strand breaks, and V(D)J recombination product formation defects. Here we show that the IR repair, DNA end binding and DNA-PK defects in Ku70-/- embryonic stem cells can be counteracted by introducing epitope-tagged wild-type Ku70 cDNA. Truncations and chimeras of Ku70 were used to identify the regions necessary for DNA end binding and IR repair. Site-specific mutational analysis revealed a core region of Ku70 responsible for DNA end binding and heterodimerization. The propensity for Ku70 to associate with Ku80 and to bind DNA correlates with the ability to activate DNA-PK, although two mutants showed that the roles of Ku70 in DNA-PK activation and IR repair are separate. Mutation of DNA-PK autophosphorylation sites and other structural motifs in Ku70 showed that these sites are not necessary for IR repair in vivo. These studies reveal Ku70 features required for double-strand break repair.     

NF-kappaB p65 regulates nuclear translocation of Ku70 via degradation of heat shock cognate protein 70 in pancreatic acinar AR42J cells

Ku proteins such as Ku70 and Ku80 play key roles in multiple nuclear processes. Nuclear translocation of Ku70 is independent of Ku80 translocation and mediated by nuclear localization signal (NLS) receptors including importin-alpha. In the present study using pancreatic acinar AR42J cells, heat shock cognate protein 70 (Hsc70) was identified as the protein associated with NLS of Ku70. Interaction of Ku70 with importin-alpha and nuclear translocation of Ku70 was suppressed by overexpression of Hsc70, but enhanced by downregulation of Hsc70. The results suggest that the formation of Ku70 complex with Hsc70 prevents NLS of Ku70 from access of importin-alpha and inhibits nuclear translocation of Ku70. Since NF-kappaB p65 activation induced the decrease of Hsc70 level, the interaction of Ku70 with importin-alpha and nuclear translocation of Ku70 increased upon the activation of NF-kappaB p65. NF-kappaB p65 induced cell proliferation through decrease of Hsc70 levels and increase of nuclear translocation of Ku70. In the cells treated with cerulein as a physiological stimulus to activate NF-kappaB p65, nuclear translocation of Ku70 increased through NF-kappaB p65-mediated decrease of Hsc70 level. The results suggest that the involvement of NF-kappaB p65 in nuclear translocation of Ku70 may be mediated by Hsc70 degradation, which may play a key role in cell proliferation of pancreatic acinar AR42J cells.     

Ku70 suppresses the apoptotic translocation of Bax to mitochondria

Bax induces mitochondrial-dependent cell death signals in mammalian cells. However, the mechanism of how Bax is kept inactive has remained unclear. Yeast-based functional screening of Bax inhibitors from mammalian cDNA libraries identified Ku70 as a new Bax suppressor. Bax-mediated apoptosis was suppressed by overexpression of Ku70 in mammalian cells, but enhanced by downregulation of Ku70. We found that Ku70 interacts with Bax, and that the carboxyl terminus of Ku70 and the amino terminus of Bax are required for this interaction. Bax is known to translocate from the cytosol to mitochondria when cells receive apoptotic stimuli. We found that Ku70 blocks the mitochondrial translocation of Bax. These results suggest that in addition to its previously recognized DNA repair activity in the nucleus, Ku70 has a cytoprotective function in the cytosol that controls the localization of Bax.     

Production and characterization of recombinant human Ku antigen.

Ku is an ubiquitous nuclear heterodimeric protein consisting of p70 and p86 subunits that binds double-stranded DNA termini and associates with chromosomes in vivo. It was originally described as an autoantigen in patients with certain autoimmune diseases. The individual subunits of Ku have been difficult to isolate from human cells without denaturation and attempts to produce functional recombinant Ku have been largely unsuccessful. Here, we utilize two recombinant baculoviral vectors that carry p70 or p86 cDNA and express the Ku subunits individually as well as assemble them into the complete Ku heterodimer. In an electrophoretic mobility shift assay, recombinant Ku binds to linear double-stranded DNA but not to supercoiled, nicked circular, nor linear single-stranded DNA. Neither subunit binds DNA by itself indicating that heterodimerization is essential for function. We also describe a simple purification method for the isolation of highly purified recombinant Ku using a hexahistidine tag. The baculovirus expression system provides a stable and efficient source of not only the p70 and p86 subunits but also the functional Ku heterodimer.     

Heterozygous inactivation of human Ku70/Ku86 heterodimer does not affect cell growth, double-strand break repair, or genome integrity

Ku, the heterodimer of Ku70 and Ku86, plays crucial roles in non-homologous end-joining (NHEJ), a major pathway for repairing DNA double-strand breaks (DSBs) in mammalian cells. It has recently been reported that heterozygous disruption of the human KU86 locus results in haploinsufficient phenotypes, including retarded growth, increased radiosensitivity, elevated p53 levels and shortened telomeres. In this paper, however, we show that heterozygous inactivation of either the KU70 or KU86 gene does not cause any defects in cell proliferation or DSB repair in human somatic cells. Moreover, although these heterozygous cell lines express reduced levels of both Ku70 and Ku86, they appear to maintain overall genome integrity with no elevated p53 levels or telomere shortening. These results clearly indicate that Ku haploinsufficiency is not a commonly observed phenomenon in human cells. Our data also suggest that the impact of KU70/KU86 mutations on telomere metabolism varies between cell types in humans.     

Ionizing radiation exposure results in up-regulation of Ku70 via a p53/ataxia-telangiectasia-mutated protein-dependent mechanism

Genome damaging events, such as gamma-irradiation exposure, result in the induction of pathways that activate DNA repair mechanisms, halt cell cycle progression, and/or trigger apoptosis. We have investigated the effects of gamma-irradiation on cellular levels of the Ku autoantigens. Ku70 and Ku80 have been shown to form a heterodimeric complex that can bind tightly to free DNA ends and activate the protein kinase DNA-PKcs. We have found that irradiation results in an up-regulation of cellular levels of Ku70, but not Ku80, and that this enhanced level of Ku70 accumulates within the nucleus. Further, we uncovered that the postirradiation up-regulation of Ku70 utilizes a mechanism that is dependent on both p53 and damage response protein kinase ATM (ataxia-telangiectasia-mutated); however, the activation of DNA-PK does not require Ku70 up-regulation. These findings suggest that Ku70 up-regulation provides the cell with a means of assuring either proper DNA repair or an appropriate response to DNA damage independent of DNA-PKcs activation.     

Characterization of the 70KDA component of the human Ku autoantigen expressed in insect cell nuclei using a recombinant baculovirus vector.

The Ku autoantigen is a human nuclear, DNA-binding heterodimer of 70kDa and 86kDa proteins. It is the target of autoantibodies in several autoimmune diseases. We now report the expression of a cDNA encoding the 70kDa Ku protein. Large amounts of protein were obtained using a recombinant baculovirus vector, in contrast with earlier unsuccessful attempts using other expression systems. We demonstrate that the 70kDa Ku protein is targeted to the nucleus and is associated with the nuclear matrix when expressed in the absence of the 86kDa Ku component. No post-translational modifications were observed. The 70kDa protein binds double and single-stranded DNA with very high affinity. Our results suggest that the baculovirus expression system may be of widespread use in the production and characterization of human autoantigens.     

Identification of Ki (Ku, p70/p80) autoantigens and analysis of anti-Ki autoantibody reactivity

Anti-Ki (Ku, p70/p80) autoantibodies, named after the prototype patient Kikuta by Tojo et al., occur in approximately 10% of patients with SLE, often in association with anti-Sm autoantibodies. The immunofluorescent staining pattern characteristic of anti-Ki antibodies is diffuse speckled nuclear, although some substrates show nucleolar staining as well. Anti-Ki sera specifically immunoprecipitated two protein antigens, Ki86 (Mr 86,000) and Ki66 (Mr 66,000), from radiolabeled cell extracts. The Ki system was found to be immunologically identical to the Ku system described by Mimori et al. and the p70/p80 system described by Reeves. The Ki primary in vitro translation products were identified and proved similar in size to the cellular antigens. The Ki antigens were purified from human spleen by immunoaffinity chromatography followed by SDS-PAGE. The purified Ki antigens proved to be closely related by amino acid composition, and did not appear to be phosphorylated, glycosylated, or associated with RNA. The Ki antigens were found to bind to DNA, in agreement with the observations on the Ku and p70/p80 antigens. They were found to be widely conserved in mammals and were coordinately expressed in all tissues tested. Anti-Ki autoantibodies were purified by antigen-affinity chromatography and were tested by immunoblotting. The antibodies were classified as class I, II, or III, depending on their reactivity with the Ki antigens in immunoblots. Class I antibodies cross-reacted with both Ki antigens, class II antibodies reacted solely with Ki66, and class III antibodies reacted solely with Ki86. These results suggest that at least three different epitopes are present on the Ki autoantigens and that patients differ in their autoantibody response to each epitope.     

Interaction of a cyclin E fragment with Ku70 regulates Bax-mediated apoptosis

The cyclin E/Cdk2 complex plays an essential role in the G(1)/S cell cycle transition and DNA replication. Earlier we showed that in hematopoietic tumor cells, caspase-mediated cleavage of cyclin E generates p18-cyclin E, which is unable to interact with Cdk2 and therefore plays a role independent of the cell cycle. The expression of a cleavage-resistant cyclin E mutant greatly diminishes apoptosis, indicating the critical role of cyclin E cleavage. p18-cyclin E expression can induce apoptosis or sensitization to apoptotic stimuli in many cell types. Here we identify Ku70 as a specific p18-cyclin E-interacting partner. In hematopoietic tumor cell lines, the association of p18-cyclin E with Ku70 induces the dissociation of Bax from Ku70, followed by Bax activation. This mechanism of Bax activation leads to the amplification of the apoptosis signal in all tumor cell lines examined. N-terminal Ku70 deletion mutants are unable to bind to p18-cyclin E to regulate its apoptotic effect. p18-cyclin E-mediated amplification of apoptosis is dependent on Bax and Ku70 being greatly diminished in Ku70(-/-) and Bax(-/-) mouse embryo fibroblasts and in hematopoietic cells where Bax knockdown was achieved by short interfering RNA. The p18-cyclin E/Ku70 and Bax/Ku70 interactions provide a balance between apoptosis and the survival of cells exposed to genotoxic stress.     

Accumulation of Ku70 at DNA double-strand breaks in living epithelial cells

Ku70 and Ku80 play an essential role in the DNA double-strand break (DSB) repair pathway, i.e., nonhomologous DNA-end-joining (NHEJ). No accumulation mechanisms of Ku70 at DSBs have been clarified in detail, although the accumulation mechanism of Ku70 at DSBs plays key roles in regulating the NHEJ activity. Here, we show the essential domains for the accumulation and function of Ku70 at DSBs in living lung epithelial cells. Our results showed that EGFP-Ku70 accumulation at DSBs began immediately after irradiation. Our findings demonstrate that three domains of Ku70, i.e., the α/β, DNA-binding, and Ku80-binding domains, but not the SAP domain, are necessary for the accumulation at or recognition of DSBs in the early stage after irradiation. Moreover, our findings demonstrate that the leucine at amino acid 385 of Ku70 in the Ku80-binding domain, but not the three target amino acids for acetylation in the DNA-binding domain, is involved in the localization and accumulation of Ku70 at DSBs. Furthermore, accumulations of XRCC4 and XLF, but not that of Artemis, at DSBs are dependent on the presence of Ku70. These findings suggest that Artemis can work in not only the Ku-dependent repair process, but also the Ku-independent process at DSBs in living epithelial cells.