Yin-Chang Liu

Presentation of autoantibody to proliferating cell nuclear antigen in patients with chronic hepatitis B and C virus infection.

OBJECTIVES To study the association of antibodies to proliferating cell nuclear antigen (PCNA) in patients with chronic hepatitis B (HBV) and C (HCV) virus infection. METHODS Sera from 243 patients with chronic HBV infection; 379 patients with chronic HCV infection; 80 patients with systemic lupus erythematosus (SLE); 28 patients with rheumatoid arthritis; 15 patients with Sjogren’s syndrome; eight with polymyositis; eight with primary biliary cirrhosis; and 33 healthy control subjects were tested for the presentation of anti-PCNA antibodies by enzyme linked immunosorbent assay (ELISA) and immunoblotting using recombinant PCNA as antigen. The distribution of immunoglobulin isotypes of anti-PCNA antibody was measured by ELISA assay. RESULTS By ELISA, anti-PCNA antibodies were detected in 30 (12.3%) patients with chronic HBV infection, 71 (18.7%) patients with chronic HCV infection, and five (6.3%) patients with SLE. The inhibition of binding with these sera by purified PCNA was shown to exceed 71%. By immunoblotting, the frequency of anti-PCNA in patients with chronic HBV and HCV infection was 17 of 243 (7%) and 41 of 379 (11%), respectively. Absorption studies on indirect immunofluorescence showed the typical nuclear speckled staining pattern by anti-PCNA sera was abolished by preincubation of sera with PCNA. Anti-PCNA antibody was not detected in sera from patients with autoimmune diseases except SLE. Anti-PCNA antibodies in patients with chronic HBV and HCV infection were predominantly IgG. CONCLUSION These data suggest that anti-PCNA antibody are also present in patients with chronic HBV and HCV infection. Anti-PCNA antibody may not be specific for SLE.

Induction of Oxidative DNA Damage by Flavonoids of Propolis: Its Mechanism and Implication about Antioxidant Capacity

Propolis from beehives is commonly used as a home remedy for various purposes including as a topical antiseptic. Despite its antioxidant capacity, propolis induces oxidative DNA damage. In exploring the underlying mechanism, we found that the induction of oxidative DNA damage is attributed to the hydrogen peroxide (H(2)O(2)) produced by propolis. The formation of H(2)O(2) can take place without the participation of cells but requires the presence of transition metal ions such as iron. Flavonoids such as galangin, chrysin, and pinocembrin that are commonly detected in propolis have the capacity to induce oxidative DNA damage, and that capacity correlates with the production of H(2)O(2), suggesting the involvement of flavonoids in propolis in this process. On the basis of these results, we propose that the flavonoids of propolis serve as temporary carriers of electrons received from transition metal ions that are relayed to oxygen molecules to subsequently generate superoxide and H(2)O(2). In addition, propolis induces oxidative DNA damage that is subject to repair, and propolis-treated cells show a lower level of DNA damage level when challenged with another oxidative agent such as amoxicillin. This is reminiscent of an adaptive response that might contribute to the beneficial effects of propolis.

Direct involvement of the tumor suppressor p53 in nucleotide excision repair

The tumor suppressor p53 enhances repair of UVC-induced DNA damage. The comet-NE assay, a conventional alkaline comet assay which includes a nuclear digestion step, was used to examine the effects of p53 on the excision activity of nuclear extracts (NEs). In contrast with untreated NEs, NEs immunodepleted of p53 or NEs of p53-null cells were unable to excise UVC-induced DNA adducts. Introduction of p53 by transfection restored the excision activity to NEs of p53-null cells. Deletion of the N-terminal 99 amino acids and/or the C-terminal 85 amino acids of p53 barely affected the excision activity, whereas further deletion of the C-terminus of p53 by another 10 amino acids completely abolished the excision activity of NEs. Immunostaining following localized UV irradiation was used to examine the effects of p53 on the recruitment of repair proteins for nucleotide excision repair (NER). Although recruitment of XPC occurred regardless of the presence of p53, the recruitment of XPB was p53-dependent. However, p53 with the 95 amino acid deletion at its C-terminus was unable to support this recruitment of XPB. Consistently, intact p53 (but not the C-terminal 95 residue truncated version) was detected in co-immunoprecipitation assays with an anti-XPB antibody. These results support the hypothesis that p53 facilitates NER through direct involvement by protein-protein interactions.

UV inducibility of rat proliferating cell nuclear antigen gene promoter

Proliferating cell nuclear antigen (PCNA), also known as a cofactor of DNA polymerase δ, is required for eukaryotic cell DNA synthesis and nucleotide excision repair. Expression of PCNA gene is growth‐regulated and UV inducible. In our previous study, we have observed that the rat PCNA promoter has the serum responsiveness. In this study, we demonstrate its UV inducibility in CHO.K1 cells. The UV induction of the rat PCNA promoter activity was dose‐dependent in the cells synchronized at different phases. In addition, the sequences of the promoter responsible for the UV inducibility were delimited to the region between nucleotides −70 and +125, which contains an AP‐1 site and a downstream proximal ATF/CRE site. While mutation of the AP‐1 site abrogated the UV inducibility, mutation of the ATF/CRE site enhanced the UV inducibility, suggesting that the two sites play different roles in the UV induction of the promoter. In addition, the role of p53 in the UV induction of rat PCNA promoter was investigated. We found that exogenous p53 was unable to mimic the UV irradiation to induce rat PCNA promoter and that the UV induction of the rat PCNA promoter was seen in p53 deficient cells. Therefore, it is unlikely that the UV induction of the rat PCNA promoter is p53 dependent. J. Cell. Biochem. 73:423–432, 1999.

Molecular cloning and characterization of porcine cDNA encoding a 90-kDa heat shock protein and its expression following hyperthermia

We have isolated and sequenced cDNA clones encoding a 90-kDa heat shock protein (HSP90) from a porcine brain cDNA library. The sequence of the 2202-nucleotide coding region showed 88.6% homology with that of the human homologue. Moreover, the deduced amino acid sequence of the porcine hsp90 cDNA was 99.7% identical to that of the human counterpart, with a difference of only three amino acids in a total of 733 residues. Expression of the gene was greatly increased in cultured cells during recovery from heat shock treatment at 45 degrees C for 60 min. Three major transcripts 2.2, 3.0, and 4.1kb in size were detected by Northern blot hybridization. These transcripts were further identified in a whole-pig hyperthermia experiment. These three hsp90 transcripts were constitutively expressed in porcine tissues including kidney, liver, brain, and heart, and their levels were markedly enhanced during recovery from 30-min hyperthermia treatment at 43 degrees C. Furthermore, we found that HSP90 was preferentially expressed in pituitary gland, brain, adrenal gland, and testis, in comparison to the other tissues.

Expression of tumor suppressor p53 facilitates DNA repair but not UV-induced G2/M arrest or apoptosis in Chinese hamster ovary CHO-K1 cells.

Tumor suppressor p53 is an essential regulator in mammalian cellular responses to DNA damage including cell cycle arrest and apoptosis. Our study with Chinese hamster ovary CHO‐K1 cells indicates that when p53 expression and its transactivation capacity was inhibited by siRNA, UVC‐induced G2/M arrest or apoptosis were unaffected as revealed by flow cyotmetric analyses and other measurements. However, inhibition of p53 rendered the cells slower to repair UV‐induced damages upon a plasmid as shown in host cell reactivation assay. Furthermore, the nuclear extract (NE) of p53 siRNA‐treated cells was inactive to excise the UV‐induced DNA adducts as analyzed by comet assay. Consistently, the immunodepletion of p53 also deprived the excision activity of the NE in the similar experiment. Thus, tumor suppressor p53 of CHO‐K1 cells may facilitate removal of UV‐induced DNA damages partly via its involvement in the repair mechanism. J. Cell. Biochem. 103: 528–537, 2008.

Anti-PCNA autoantibodies preferentially recognize C-terminal of PCNA in patients with chronic hepatitis B virus infection

We previously reported anti‐PCNA autoantibodies in sera from patients with chronic HBV and HCV infection. To analyse the antigenic regions on proliferating cell nuclear antigen (PCNA) that confer autoantibody binding in patients with chronic hepatitis B (HBV) and C (HCV) infection, eight constructs including one wild type PCNA, one mutant type Y114A_PCNA and six C‐ or N‐terminal PCNA truncations were generated. Sera from 185 patients with systemic lupus erythematosus (SLE), 178 with chronic HBV and 163 with chronic HCV infection, and 68 healthy individuals were examined for the presentation of anti‐PCNA antibodies by enzyme linked immunosorbent assay (ELISA). By ELISA, anti‐PCNA positive sera from patients with SLE, chronic HBV and HCV infection preferentially recognized the wild type PCNA more than the mutant type Y114A_PCNA (P < 0·05). The inhibition of binding by purified full‐length rPCNA proteins with anti‐PCNA positive sera was shown to exceed 70%. The inhibition of binding by purified truncated rPCNA proteins with sera from patients with chronic HBV and HCV infection and SLE was shown to confer dominant binding in TL2 and TL3. Moreover, the higher frequency of inhibition by using TL3 was found in patients with chronic HBV infection. These data indicate that anti‐PCNA autoantibodies preferentially recognize C‐terminal of PCNA in patients with chronic HBV infection and may also provide advanced understanding between viral infection and autoimmunity for further study.

Geldanamycin inhibits trichostatin A-induced cell death and histone H4 hyperacetylation in COS-7 cells.

As widely believed treating cells with trichostatin A (TSA), an inhibitor of histone deacetylase, results in histone H4 hyperacetylation and cell cycle arrest. This compound is often compared with other potential anticancer drugs in cell cycle, proliferation and differentiation research. Furthermore, geldanamycin (GA), a 90-kDa heat shock protein (HSP90) specific inhibitor, is a well-known potential anticancer agent. This study examines whether GA can affect the cellular functions induced by TSA. When using TSA treatment, although caused COS-7 cell death, pretreatment of 0.5 microg/ml GA for 30 min and an addition of 50 ng/ml TSA (GA + TSA) apparently averted cell death. Our results indicated that the cell survival rate was only approximately 20% when prolonged treatment was undertaken with 50 ng/ml TSA (TSA) alone for 24 h. In contrast, the cell survival rate was enhanced by two folds when treating with GA + TSA. Furthermore, DNA fragmentation assay revealed that fragmented DNA was produced 8 h after prolonged treatment with TSA alone. Within 16 h, the apoptotic percentages of TSA-treated cells were between 15-25%. In contrast, the other treatments did not exceed 6%. Furthermore, GA inhibited TSA-induced histone H4 hyperacetylation. Western blotting analysis further demonstrated that the HSP70 levels did not significantly increase in TSA-treated cells. However, the accumulated 70-kDa heat shock protein (HSP70) markedly increased up to 2 to 3 folds at 8 h in GA- and GA + TSA-treated cells, and the maximum amount up to 5 to 7 folds at 20 h. Conversely, HSP90 did not markedly increase in all treatments. Based on the results in this study, we suggest that apoptosis induced by TSA can be prevented by GA-induced increment of heat shock proteins, particularly HSP70.

Serum responsiveness of the rat PCNA promoter involves the proximal ATF and AP-1 sites

We have previously shown that the rat PCNA (proliferating cell nuclear antigen) gene promoter is responsive to serum stimulation. In this study, the sequence of the promoter responsive to serum stimulation has been localized in the region between nucleotides −70 and +125 relative to the transcription initiation site. This region contains an ATF site (nucleotides −51 to −44) and an AP‐1 site (nucleotides −64 to −58). Mutation at either the ATF or the AP‐1 site reduced the serum responsiveness of the promoter. In gel mobility shift assays, nuclear extracts from serum stimulated cells, compared to those from quiescent cells, exhibit an increasing binding activity toward a promoter related oligonucleotide (−70 to −42) which includes the ATF site and the AP‐1 site. Formation of the DNA:protein complexes requires the simultaneous involvement of ATF and AP‐1 sites as either element can abrogate the complexes in the competition experiment. Both the distance and sequence are essential to complex formation. Moreover, ATF‐1 but not ATF‐2 (or CREB) has been identified as a major component of the complexes in the antibody supershift or interference experiment. The results of this study suggest that ATF‐1 in association with other factors is involved in regulating the serum stimulation of the rat PCNA promoter activity via the proximal ATF and AP‐1 sites.

Delay of gap filling during nucleotide excision repair by base excision repair: The concept of competition exemplified by the effect of propolis

Nucleotide excision repair (NER) consists of a sequence of events including DNA damage recognition, excision of the damage containing oligonucleotide, gap filling, and ligation. We found that gap filling during the repair of ultraviolet (UV)C-induced DNA lesions was inhibited by various compounds, e.g., amoxicillin, and mixtures, e.g., propolis, the materials that could induce oxidative DNA damage in serum-supplemented cell cultures. Such inhibitory effect was also demonstrated by the immunostaining experiment and host cell reactivation assay. In this study, we link the repair of oxidative DNA damage with the inhibition of gap filling. Our experimental evidence includes the following: (1) induction of oxidative DNA damage and inhibition of gap filling were quantitatively correlated; (2) although the repair of UV-induced DNA damage was delayed in the presence of propolis, the repair of propolis-induced oxidative DNA damage proceeded regardless of preexposure to UV radiation; (3) inhibition of gap filling by propolis was absent in base excision repair (BER)-deficient cells; (4) suppression of propolis-induced oxidative DNA damage by β-carotene abolished the inhibition of gap filling; and (5) inhibition of gap filling was also found with typical BER-inducing agents such as hydrogen peroxide, menadione, and methyl methanesulfonate. We propose that competition may occur between NER and BER, which results in delay of gap filling. Our study reveals the dominancy of BER over NER.