Shuji Hanai

Loss of poly(ADP-ribose) glycohydrolase causes progressive neurodegeneration in Drosophila melanogaster

Poly(ADP-ribosyl)ation has been suggested to be involved in regulation of DNA repair, transcription, centrosome duplication, and chromosome stability. However, the regulation of degradation of poly(ADP-ribose) and its significance are not well understood. Here we report a loss-of-function mutant Drosophila with regard to poly(ADP-ribose) glycohydrolase, a major hydrolyzing enzyme of poly(ADP-ribose). The mutant lacks the conserved catalytic domain of poly(ADP-ribose) glycohydrolase, and exhibits lethality in the larval stages at the normal development temperature of 25°C. However, one-fourth of the mutants progress to the adult stage at 29°C but showed progressive neurodegeneration with reduced locomotor activity and a short lifespan. In association with this, extensive accumulation of poly(ADP-ribose) could be detected in the central nervous system. These results suggest that poly(ADP-ribose) metabolism is required for maintenance of the normal function of neuronal cells. The phenotypes observed in the parg mutant might be useful to understand neurodegenerative conditions such as the Alzheimers and Parkinsons diseases that are caused by abnormal accumulation of substances in nervous tissue.

Genetic and environmental determinants of risk for cholangiocarcinoma via Opisthorchis viverrini in a densely infested area in Nakhon Phanom, northeast Thailand

Infection with Opisthorchis viverrini (OV) is associated with cholangiocarcinoma. OV is common in northeast Thailand, but less than 10% of the inhabitants develop cholangiocarcinoma. Animal experiments suggest that OV infection alone does not cause cholangiocarcinoma, and thus other environmental and genetic factors may play a role in causation. We conducted a population‐based case‐control study in which sex, age and place of residence were matched individually. Polymorphisms of GSTM1 and GSTT1 alone were not associated with risk for cholangiocarcinoma, while an elevated level of antibodies against OV (ELISA) ≥0.200 was the strongest risk indicator (odds ratio as compared to that <0.200 = 27.09 [95% confidence interval (CI): 6.30–116.57]. Compared to subjects who had a normal antibody range and the wild‐type GSTM1 gene, those who had elevated antibodies had higher odds ratios of 12.32 (95% CI: 1.60–94.85) for wild‐type GSTM1 and 23.53 (95% CI: 4.25–130.31) for the null variant thereof, respectively. Past and current regular drinkers of alcohol had higher risk [odds ratio = 5.39 (95% CI: 1.11–26.06) and 4.82 (95% CI: 1.29–18.06), respectively]. Eating fermented products was an independent risk factor. Smokers or consumers of fermented fish had substantially increased risk if they were past or current drinkers. Infection with OV correlates strongly with cholangiocarcinoma, susceptibility to which may be possibly associated with GSTM1 polymorphism. Alcohol may affect metabolic pathways of endogenous and exogenous nitrosamines.

Subcellular localization of poly(ADP-ribose) glycohydrolase in mammalian cells.

Posttranslational modification plays important roles in a range of cellular functions. Poly(ADP-ribosyl)ation influences DNA repair, transcription, centrosome duplication, and chromosome stability. Poly(ADP-ribose) attached to acceptor proteins should be properly hydrolyzed by poly(ADP-ribose) glycohydrolase (PARG). However the subcellular localization and the role of PARG have not been well characterized. Here, we transiently expressed GFP- or Myc-tagged human PARG in mammalian cells and revealed that the subcellular distribution of human PARG changes dramatically during the cell cycle. GFP-hPARG is found almost exclusively in the nucleus during interphase. During mitosis, most GFP-hPARG protein localizes to the cytoplasm and hardly any GFP-hPARG protein is found associated with the chromosomes. Furthermore, we found that GFP-hPARG localizes to the centrosomes during mitosis. Our findings suggest that shuttling of PARG between nucleus and cytoplasm and proper control of poly(ADP-ribose) metabolism throughout the cell cycle may play an important role in regulating cell cycle progression and centrosome duplication.

Altered gene expression in Opisthorchis viverrini‐associated cholangiocarcinoma in hamster model

Cholangiocarcinoma (CCA) induced by liver fluke (Opisthorchis viverrini, Ov) infection is one of the most common and serious disease in northeast Thailand. To elucidate the molecular mechanism of cholangiocarcinogenesis induced by Ov infection, we employed a hamster model of CCA induced by Ov and N‐nitrosodimethylamine and analyzed candidate genes involved in CCA using fluorescence differential display‐PCR. Of 149 differentially amplified bands we identified, the upregulation of 23 transcripts and downregulation of 1 transcript related to CCA hamsters were confirmed by a reverse northern macroarray blot. The upregulated genes include signal transduction protein kinase A regulatory subunit Iα (Prkar1a), myristoylated alanine‐rich protein kinase C substrate, transcriptional factor LIM‐4‐only domain, oxysterol‐binding protein involved in lipid metabolism, splicing regulatory protein 9, ubiquitin conjugating enzyme involved in protein degradation, β tubulin, β actin, and collagen type VI. Quantitative real‐time PCR confirmed that the expression of Prkar1a was significantly higher in CCA and its precursor lesion when compared with normal liver and normal gall bladder epithelia (P < 0.05). Prkar1a expression tended to increase along with the progression of biliary transformation from hyperplasia and precancerous lesions to carcinoma. These findings contribute to our understanding of the processes involved in the molecular carcinogenesis of CCA in order to provide a unique perspective on the development of new chemotherapeutics in future.

POLY(ADP-RIBOSE) POLYMERASE INTERACTS WITH NOVEL DROSOPHILA RIBOSOMAL PROTEINS, L22 AND L23A, WITH UNIQUE HISTONE-LIKE AMINO-TERMINAL EXTENSIONS

Poly(ADP-ribose) polymerase (PARP) is a nuclear enzyme that recognizes and binds to the nicks and ends of DNA, and catalyses successive ADP-ribosylation reactions. To clarify the function of PARP at the molecular level, we searched proteins which interact with PARP. In the auto-modification domain of PARP in Drosophila, there is a putative leucine-zipper motif which can interact with other protein molecules. To find interacting proteins we examined the auto-modification domain of Drosophila PARP, using the Far-Western screening method. From six independent cDNA clones isolated, we characterized two clones, PBP-3 and PBP-12. The predicted amino acid sequences from 109 to 269 of PBP-3 and from 184 to 312 of PBP-12 had more than 62% identities to mammalian L23a (rpl23a) and L22 (rpl22), the ribosomal proteins of the large subunit. This indicated that PBP-3 and PBP-12 are Drosophila homologues of L23a and L22, respectively. These Drosophila ribosomal protein L22 and L23a have additional Ala-, Lys- and Pro-rich sequences at the amino terminus, which have a resemblance to the carboxy-terminal portion of histone H1. Thus, Drosophila L22 and L23a might have two functions, namely the role of DNA-binding similar to histone H1 and the role of organizing the ribosome.

Integration of human T‐cell leukemia virus type 1 in genes of leukemia cells of patients with adult T‐cell leukemia

Adult T‐cell leukemia (ATL) occurs after a long latent period of persistent infection by human T‐cell leukemia virus type 1 (HTLV‐1). However, the mechanism of oncogenesis by HTLV‐1 remains to be clarified. It was reported that the incidence curve of ATL versus age was consistent with a multistage carcinogenesis model. Although HTLV‐1 is an oncogenic retrovirus, a mechanism of carcinogenesis in ATL by insertional mutagenesis as one step during multistage carcinogenesis has not been considered thus far, because the exact integration sites on the chromosome have not been analyzed. Here we determined the precise HTLV‐1 integration sites on the human chromosome, by taking advantage of the recently available human genome database. We isolated 25 integration sites of HTLV‐1 from 23 cases of ATL. Interestingly, 13 (52%) of the integration sites were within genes, a rate significantly higher than that expected in the case of random integration (P=0.043, ?2 test). These results suggest that preferential integration into genes at the first infection is a characteristic of HTLV‐1. However considering that some of the genes are related to the regulation of cell growth, the integration of HTLV‐1 into or near growth‐related genes might contribute to the clonal selection of HTLV‐1‐infected cells during multistage carcinogenesis of ATL.

Genetic and functional analysis of PARP, a DNA strand break-binding enzyme

Poly(ADP-ribose) polymerase (PARP) is a nuclear enzyme activated by binding to a single- or double-strand break of DNA and is one of the death substrates for caspase-3 in apoptosis. The nuclear function of PARP is well studied and recent PARP-knockout studies indicate that PARP takes part in chromosomal stability. To analyze the effect of PARP overexpression, or loss of function, we have cloned PARP cDNA and the gene from Drosophila melanogaster and studied its function in developmental stages. Organization of exons corresponds to the functional domains of PARP. An alternatively spliced form of PARP lacking exon 5, which encodes the auto-modification domain, is found in Drosophila. Expression of the PARP gene is at high levels in embryos at 0-6h after egg laying and gradually decreased. In situ mRNA hybridization indicates localization of PARP mRNA in cells along the central nervous system at a late stage of embryogenesis. Overexpression of the gene in the developing eye primordia of D. melanogaster is an excellent experimental model to analyze the cell cycle and programmed cell death. We introduced PARP expression vector overexpresses PARP in the eye discs of Drosophila, and established the PARP transgenic flies by P element-mediated germ line transformation. These flies showed mild roughening of the normally smooth ommatidial lattice involving tissue polarity disruption characterized by missrotation and incorrect chirality of ommatidia. Possible mechanisms of involvement of PARP in the development are discussed.

Human T-Cell Leukemia Virus Type 1 (HTLV-1) Infection of Mice: Proliferation of Cell Clones with Integrated HTLV-1 Provirus in Lymphoid Organs

ABSTRACT Human T-cell leukemia virus type 1 (HTLV-1) is suggested to cause adult T-cell leukemia after 40 to 50 years of latency in a small percentage of carriers. However, little is known about the pathophysiology of the latent period and the reservoir organs where polyclonal proliferation of cells harboring integrated provirus occurs. The availability of animal models would be useful to analyze the latent period of HTLV-1 infection. At 18 months after HTLV-1 infection of C3H/HeJ mice inoculated with the MT-2 cell line, which is an HTLV-1-producing human T-cell line, HTLV-1 provirus was detected in spleen DNA from eight of nine mice. No more than around 100 proviruses were found per 105 spleen cells. Cellular sequences flanking the 3′ long terminal repeat (LTR) and the clonalities of the cells which harbor integrated HTLV-1 provirus were analyzed by linker-mediated PCR. The results showed that the flanking sequences are of mouse genome origin and that polyclonal proliferation of the spleen cells harboring integrated HTLV-1 provirus had occurred in three mice. A sequence flanking the 5′ LTR was isolated from one of the mice and revealed the presence of a 6-nucleotide duplication of cellular sequences, consistent with typical retroviral integration. Moreover, PCR was performed on DNA from infected tissues, with LTR primers and primers derived from seven novel flanking sequences of the three mice. Data revealed that the expected PCR products were found from lymphatic tissues of the same mouse, suggesting that the lymphatic tissues were the reservoir organs for the infected and proliferating cell clones. The mouse model described here should be useful for analysis of the carrier state of HTLV-1 infection in humans.

The genetic background as a determinant of human T-cell leukemia virus type 1 proviral load

Human T-cell leukemia virus type 1 (HTLV-1) is etiologically linked with HTLV-1-associated diseases. HTLV-1 proviral load is higher in persons with adult T-cell leukemia and HTLV-1-associated myelopathy/tropical spastic paraparesis than in asymptomatic carriers. However there are little data available on the factors controlling HTLV-1 proviral load in carriers. To study the effect of genetic background on HTLV-1 proviral load, we employed a mouse model of HTLV-1 infection that we had established. Here we analyzed nine strains of mice and found there is a great variation of proviral load among mouse strains that is not necessarily dependent on major histocompatibility complex. The antibody response is also different among these strains. To our knowledge, this is the first demonstration of the importance of the genetic background other than major histocompatibility complex controlling the HTLV-1 proviral load.

Reduction of human T-cell leukemia virus type-1 infection in mice lacking nuclear factor-κB-inducing kinase

Human T‐cell lymphotropic virus type 1 (HTLV‐1) causes adult T‐cell leukemia and inflammatory disorders. Aberrant activation of nuclear factor‐κB (NF‐κB) has been linked to HTLV‐1 pathogenesis and to various kinds of cancers, including adult T‐cell leukemia. NF‐κB‐inducing kinase (NIK) is critical for non‐canonical activation of NF‐κB and for the development of lymphoid organs. HTLV‐1 activates NF‐κB by the non‐canonical pathway, but examination of the role of NIK in proliferation of HTLV‐1‐infected cells in vivo has been hindered by lack of a suitable animal model. Alymphoplasia (aly/aly) mice bear a mutation of NIK, resulting in defects in the development of lymphoid organs and severe deficiencies in both humoral and cell‐mediated immunity. In the present study we therefore used a mouse model of HTLV‐1 infection with aly/aly mice. The number of HTLV‐1‐infected cells in the reservoir organs in aly/aly mice was significantly smaller than in the control group 1 month after infection. In addition, aly/aly mice did not maintain provirus for 1 year and antibodies against HTLV‐1 were undetectable. These results demonstrate that the absence of functional NIK impairs primary HTLV‐1 proliferation and abolishes the maintenance of provirus. Interestingly, clonal proliferation of HTLV‐1‐infected mouse cells was not detected in aly/aly mice, which is consistent with the lack of HTLV‐1 persistence. These observations imply that the clonal proliferation of HTLV‐1‐infected cells in secondary lymphoid organs might be important for HTLV‐1 persistence. (Cancer Sci 2008; 99: 872–878)