Crystal structure of the worm NitFhit Rosetta Stone protein reveals a Nit tetramer binding two Fhit dimers

BACKGROUND: The nucleotide-binding protein Fhit, among the earliest and most frequently inactivated proteins in lung cancer, suppresses tumor formation by inducing apoptosis. In invertebrates, Fhit is encoded as a fusion protein with Nit, a member of the nitrilase superfamily. In mice, the Nit1 and Fhit genes have nearly identical expression profiles. According to the Rosetta Stone hypothesis, if the separate Nit and Fhit genes could be shown to occur in the same subset of genomes (that is, to share a phylogenetic profile), then the existence of a fusion protein in invertebrates and the coordinated expression of separate mRNAs in mouse suggest that Nit and Fhit function in the same pathway and that the structure of invertebrate NitFhit may reflect the nature of Nit-Fhit interactions. RESULTS: To satisfy the phylogenetic profile criterion for functional significance of protein fusion events, we cloned additional Nit homologs from organisms with Fhit homologs. We used fluorescent nucleotide analogs of ApppA to follow the purification and to characterize the nucleotide specificity of NitFhit from Caenorhabditis elegans, crystallized the 200 kDa tetrameric complex, and solved the structure of NitFhit from a single mercury derivative phased by two-wavelength anomalous diffraction. CONCLUSIONS: Nit monomers possess a new alpha-beta-beta-alpha sandwich fold with a presumptive Cys-Glu-Lys catalytic triad. Nit assembles into a tetrameric, 52-stranded beta box that binds Fhit dimers at opposite poles and displays Nit active sites around the middle of the complex. The most carboxy-terminal beta strand of each Nit monomer exits the core of the Nit tetramer and interacts with Fhit. Residence in the NitFhit complex does not alter the nucleotide specificity of Fhit dimers, which are oriented with ApppA-binding surfaces away from Nit.     

Hits, Fhits and Nits: beyond enzymatic function

We have briefly summarized what is known about these proteins, but in closing wish to feature the outstanding questions. Hint1 was discovered mistakenly as an inhibitor of Protein Kinase C and designated Pkci, a designation that still confuses the literature. The other Hint family members were discovered by homology to Hint1. Aprataxin was discovered as a result of the hunt for a gene responsible for AOA1. Fhit was discovered through cloning of a familial chromosome translocation breakpoint on chromosome 3 that interrupts the large FHIT gene within an intron, in the FRA3B chromosome region (Ohta et al., 1996), now known to be the region of the human genome most susceptible to DNA damage due to replication stress (Durkin et al., 2008). The NitFhit fusion genewas discovered during searches for Fhit homologs in flies and worms because the fly/worm Nit polypeptide is fused to the 5'-end of the Fhit gene; the mammalian Nit gene family was discovered because of the NitFhit fusion gene, in searches for homologs to the Nit polypeptide of the NitFhit gene. Each of the Hit family member proteins is reported to have enzymatic activities toward putative substrates involving nucleosides or dinucleosides. Most surprisingly, each of the Hit family proteins discussed has been implicated in important DNA damage response pathways and/or tumor suppression pathways. And for each of them it has been difficult to assign definite substrates, to know if the substrates and catalytic products have biological functions, to know if that function is related to the DNA damage response and suppressor functions, and to precisely define the pathways through which tumor suppression occurs. When the fly Nit sequence was found at the 5'-end of the fly Fhit gene, this gene was hailed as a Rosetta stone gene/protein that would help in discovery of the function of Fhit, because the Nit protein should be in the same signal pathway (Pace et al., 2000). However, the mammalian Nit family proteins have turned out to be at least as mysterious as the Fhit proteins, with the Nit1 substrate still unknown and the surprising finding that Nit proteins also appear to behave as tumor suppressor proteins. Whether the predicted enzymatic functions of these proteins are relevant to the observed biological functions, remain among the outstanding unanswered puzzles and raise the question: have these mammalian proteins evolved beyond the putative original enzymatic purpose, such that the catalytic function is now vestigial and subservient to signal pathways that use the protein-substrate complexes in pathways that signal apoptosis or DNA damage response? Or can these proteins be fulfilling catalytic functions independently but in parallel with signal pathway functions, as perhaps observed for Aprataxin? Or is the catalytic function indeed part of the observed biological functions, such as apoptosis and tumor suppression? Perhaps the recent, post-genomic focus on metabolomics and genome-wide investigations of signal pathway networks will lead to answers to some of these outstanding questions.     

Nit1 and Fhit tumor suppressor activities are additive

The fragile histidine triad gene (human FHIT, mouse Fhit) has been shown to act as a tumor suppressor gene. Nit1 and Fhit form a fusion protein, encoded by the NitFhit gene in flies and worms, suggesting that mammalian Nit1 and Fhit proteins, which are encoded by genes on different chromosomes in mammals, may function in the same signal pathway(s). A previous study showed that Nit1 deficiency in knockout mice confers a cancer prone phenotype, as does Fhit deficiency. We have now assessed the tumor susceptibility of Fhit^?/?Nit1^?/? mice and observed that double knockout mice develop more spontaneous and carcinogen‐induced tumors than Fhit^?/? mice, suggesting that the extent of tumor susceptibility due to Nit1 and Fhit deficiency is additive, and that Nit1 and Fhit affect distinct signal pathways in mammals. Nit1, like Fhit, is present in cytoplasm and mitochondria but not nuclei. Because Fhit deficiency affects responses to replicative and oxidative stress, we sought evidence for Nit1 function in response to such stresses in tissues and cultured cells: when treated with hydroxyurea, the normal kidney‐derived double‐deficient cells appear not to activate the pChk2 pathway and when treated with H₂O₂, show little evidence of DNA damage, compared with wild type and Fhit^?/? cells. The relevance of Nit1 deficiency to human cancers was examined in human esophageal cancer tissues, and loss of Nit1 expression was observed in 48% of esophageal adenocarcinomas. J. Cell. Biochem. 107: 1097–1106, 2009. © 2009 Wiley‐Liss, Inc.     

Growth inhibitory effect of the human NIT2 gene and its allelic imbalance in cancers

The mammalian nitrilase (Nit) protein is a member of the nitrilase superfamily whose function remains to be characterized. We now show that the nitrilase family member 2 gene (NIT2) is ubiquitously expressed in multiple tissues and encodes protein mainly distributed in the cytosol. Ectopic expression of Nit2 in HeLa cells was found to inhibit cell growth through G(2) arrest rather than by apoptosis. Consistent with this, proteomic and RT-PCR analyses showed that Nit2 up-regulated the protein and mRNA levels of 14-3-3sigma, an inhibitor of both G(2)/M progression and protein kinase B (Akt)-activated cell growth, and down-regulated 14-3-3beta, a potential oncogenic protein. Genotype analysis in four types of primary tumor tissues showed 12.5-38.5% allelic imbalance surrounding the NIT2 locus. The results demonstrated that NIT2 plays an important role in cell growth inhibition and links to human malignancies, suggesting that Nit2 may be a potential tumor suppressor candidate.     

Protein expression profiling identifies cyclophilin A as a molecular target in Fhit-mediated tumor suppression

Loss of fragile histidine triad (Fhit) expression is often associated with human malignancies, and Fhit functions as a tumor suppressor in controlling cell growth and apoptosis, although specific signal pathways are still undefined. We have used a proteomic approach to define proteins in the Fhit-mediated tumor suppression pathway. Because substitution of Tyr(114) (Y114) with phenylalanine (Y114F) diminishes Fhit functions, we did protein expression profiling to identify proteins differentially expressed in Fhit-negative H1299 lung cancer cells infected with wild-type (Ad-FHIT-wt) and Y114 mutant FHIT-expressing (Ad-FHIT-Y114F) adenoviruses. Among 12 distinct proteins that exhibited 4-fold differences in expression on comparison of the two infected cell lysates, cyclophilin A, the intracellular reporter of the immunosuppressive drug cyclosporine A, showed a remarkably decreased protein level in cells infected with Ad-FHIT-wt versus Ad-FHIT-Y114F. Conversely, loss of Fhit expression resulted in increased cyclophilin A expression in mouse tissues and cell lines. Restoration of Fhit expression led to down-regulated cyclophilin A protein expression and subsequently prevented cyclophilin A-induced up-regulation of cyclin D1, Cdk4, and resultant cell cycle progression (G(1)-S transition), which was independent of Ca(2+)/calmodulin-dependent kinase inhibitor, KN-93. Interestingly, Fhit down-modulation of phosphatase activity of calcineurin, which controls cyclin D1/Cdk4 activation, was reversed by cyclophilin A treatment in a concentration-dependent manner, a reversal that was inhibited by additional cyclosporine A treatment. Thus, cyclophilin A is a downstream target in Fhit-mediated cessation of cell cycle progression at late G(1) phase. Elucidation of the protein effectors of Fhit signaling may lead to identification of targets for lung cancer therapy.     

A Fhit-ing Role in the DNA Damage Checkpoint Response

The FHIT gene encompasses the most active common fragile site of the human genome and is thus exquisitely sensitive to intragenic alterations by DNA damaging agents, alterations that can lead to FHIT allele loss very early in the preneoplastic phase of cancer development, before or coincident with activation of the DNA damage checkpoint. Fhit protein expression is lost or reduced in many preneoplastic lesions and in >50% of cancers, Fhit knockout mice are highly susceptible to carcinogen induction of tumors and Fhit replacement in these mice by gene therapy induces apoptosis and significantly reduces tumor burden. But learning how Fhit induces apoptosis and suppresses tumors has been a challenge because interacting proteins, effectors of Fhit signals, have not been discovered.Nevertheless, the study of Fhit deficient mouse and human tissue-derived and cancer-derived cells in vitro has led to several important conclusions: repair protein-deficient cancers are more likely to be Fhit-deficient; Fhit-deficient cells show enhanced resistance to UVC, mitomycin C, camptothecin and ionizing radiation-induced cell killing, possibly due to strong activation of the ATR pathway following DNA damage; Fhit-deficient cells show higher efficiency of homologous recombination repair, a double-strand break repair pathway in mammalian cells; Fhit protein indirectly affects S-phase checkpoint and DNA repair. Finally, results of a recent study have suggested that the DNA damage-susceptible FRA3B/FHIT chromosome fragile region, paradoxically, encodes a protein, Fhit, that is necessary for protecting cells from accumulation of DNA damage, through modulation of checkpoint proteins Hus1 and phosphoChk1. Thus, inactivation of Fhit contributes to accumulation of abnormal checkpoint phenotypes in cancer development. It will be very important to determine mechanisms employed by Fhit in modulating checkpoint pathways, and to define consequences of Fhit loss in specific preneoplastic and neoplastic tissues, to provide rationales for effective replacement or reactivation of endogenous Fhit pathways in novel therapeutic or preventive approaches.     

Effect of ARHI on lung cancer cell proliferation, apoptosis and invasion in vitro

The purposes of this study were to elucidate the effects of ARHI (aplysia ras homolog I) on several biological features of lung cancer cells, including growth, proliferation and invasion, to collect experimental evidence for the future biological treatment of human lung cancer. The eukaryotic expression vector, pcDNA3.1–ARHI, was constructed and transfected into the human lung cancer cell line SK-MES-1. The biological properties of the resulting ARHI-expressing lung cancer cell line were evaluated using methyl thiazolyl tetrazolium assay, flow cytometry, and a Transwell invasion assay. Additionally, the influence of ARHI on the gene expression levels of cyclin D1, p27^KIP1, death-associated protein kinase 1 (DAPK1), and matrix metalloproteinases1/2 (MMP-1/2) was determined. Compared to the non-transfected SK-MES-1 cells and the cells transfected with the empty pcDNA3.1 plasmid, the ARHI-transfected cells displayed significantly reduced growth rates and decreased viability (P < 0.05). The ARHI-transfected cells also displayed a significantly higher percentage of cells in G1 phase (P < 0.05) and a lower percentage of cells in S phase (P < 0.05); a higher percentage of apoptosis (P < 0.05); and finally, a notable reduction in the basement membrane-penetration rate in the Transwell invasion assay (P < 0.05). Furthermore, it was determined that ARHI is capable of inhibiting the expression of cyclin D1, MMP-1, and MMP-2; however, ARHI promotes the expression of both p27^KIP1 and DAPK1 in SK-MES-1 cells. In conclusion, overexpression of ARHI gene might be associated with the inhibition of lung cancer cell growth, proliferation and invasion, and the promotion of apoptosis.     

Components of DNA damage checkpoint pathway regulate UV exposure-dependent alterations of gene expression of FHIT and WWOX at chromosome fragile sites

Common chromosome fragile sites are highly recombinogenic and susceptible to deletions during the development of environmental carcinogen-induced epithelial tumors. Previous studies showed that not only genetic but also epigenetic alterations in cancerous cells are involved in inactivation of the genes FHIT and WWOX at chromosome fragile sites, reported to be potential tumor suppressor genes. Here we investigated the effect of UV light on the gene expression. After exposure to UV, the mRNA and protein of the two genes in murine embryonic fibroblasts (MEF) were unstable, apparently at the G1-S phase of the cell cycle, which was consistent with nuclear run-on assay. A study of MEFs synchronized via a double thymidine block indicated that, after the exposure, the expression of Fhit and Wwox was reduced in E2f-1-deficient cells and markedly in wild-type cells, whereas the reduction was partially inhibited in Trp53-deficient cells; cells at the S phase seemed to be sensitive to exogenous FHIT, suggesting a role of the checkpoint at the G1-S phase in the stability of gene expression and a possible involvement of FHIT function at the S phase. The transfection experiment showed that the UV-induced decrease in expression was partially inhibited by transfection of kinase-dead Atr (ataxia telangiectasia mutated and Rad3 related), which is a sensor of UV-induced damage. Taken together, the present study showed that UV-induced alterations of the fragile site gene expression are involved at least partially in the checkpoint function, suggesting the role in the process of carcinogenesis after exposure to UV.     

Initiation of Genome Instability and Preneoplastic Processes through Loss of Fhit Expression

Genomic instability drives tumorigenesis, but how it is initiated in sporadic neoplasias is unknown. In early preneoplasias, alterations at chromosome fragile sites arise due to DNA replication stress. A frequent, perhaps earliest, genetic alteration in preneoplasias is deletion within the fragile FRA3B/FHIT locus, leading to loss of Fhit protein expression. Because common chromosome fragile sites are exquisitely sensitive to replication stress, it has been proposed that their clonal alterations in cancer cells are due to stress sensitivity rather than to a selective advantage imparted by loss of expression of fragile gene products. Here, we show in normal, transformed, and cancer-derived cell lines that Fhit-depletion causes replication stress-induced DNA double-strand breaks. Using DNA combing, we observed a defect in replication fork progression in Fhit-deficient cells that stemmed primarily from fork stalling and collapse. The likely mechanism for the role of Fhit in replication fork progression is through regulation of Thymidine kinase 1 expression and thymidine triphosphate pool levels; notably, restoration of nucleotide balance rescued DNA replication defects and suppressed DNA breakage in Fhit-deficient cells. Depletion of Fhit did not activate the DNA damage response nor cause cell cycle arrest, allowing continued cell proliferation and ongoing chromosomal instability. This finding was in accord with in vivo studies, as Fhit knockout mouse tissue showed no evidence of cell cycle arrest or senescence yet exhibited numerous somatic DNA copy number aberrations at replication stress-sensitive loci. Furthermore, cells established from Fhit knockout tissue showed rapid immortalization and selection of DNA deletions and amplifications, including amplification of the Mdm2 gene, suggesting that Fhit loss-induced genome instability facilitates transformation. We propose that loss of Fhit expression in precancerous lesions is the first step in the initiation of genomic instability, linking alterations at common fragile sites to the origin of genome instability.     

Involvement of the Fhit gene in the ionizing radiation-activated ATR/CHK1 pathway

Fragile Histidine Triad (Fhit) gene deletion, methylation, and reduced Fhit protein expression occur in about 70% of human epithelial tumors and, in some cancers, are clearly associated with tumor progression. Specific Fhit signal pathways have not been identified, although it has been shown that Fhit overexpression leads to apoptosis in many cancer cell lines. We report in this study that Fhit-/- cells derived from gene knockout mice show much stronger S and G2 checkpoint responses than their wild type counterparts. The strong checkpoint responses are regulated by the ATR/CHK1 pathway, which contributes to the radioresistance of Fhit-/- cells. These results indicate an association of Fhit gene inactivation with increased survival after DNA damage, which is related to the over-active checkpoints regulated by the ATR/CHK1 pathway. These results also suggest the potential effects of Fhit-dependent DNA damage response on tumor progression.     

Direct induction of cyclin D2 by Myc contributes to cell cycle progression and sequestration of p27.

Ectopic expression of Myc induces Cdk2 kinase activity in quiescent cells and antagonizes association of p27(kip1) with Cdk2. The target gene(s) by which Myc mediates this effect is largely unknown. We now show that p27 is rapidly and transiently sequestered by cyclin D2-Cdk4 complexes upon activation of Myc and that cyclin D2 is a direct target gene of Myc. The cyclin D2 promoter is repressed by Mad-Max complexes and de-repressed by Myc via a single highly conserved E-box element. Addition of trichostatin A to quiescent cells mimics activation of Myc and induces cyclin D2 expression, suggesting that cyclin D2 is repressed in a histone deacetylase-dependent manner in quiescent cells. Inhibition of cyclin D2 function in established cell lines, either by ectopic expression of p16 or by antibody injection, inhibits Myc-dependent dissociation of p27 from Cdk2 and Myc-induced cell cycle entry. Primary mouse fibroblasts that are cyclin D2-deficient undergo accelerated senescence in culture and are not immortalized by Myc; induction of apoptosis by Myc is unimpaired in such cells. Our data identify a downstream effector pathway that links Myc directly to cell cycle progression.     

HBXIP基因对乙肝病毒X蛋白诱导细胞凋亡的影响

探讨乙型肝炎病毒X蛋白结合蛋白(hepatitisBXinteractingprotein ,HBXIP)基因在乙型肝炎病毒X蛋白(HBX)诱导肝癌细胞凋亡时对细胞周期的影响.构建HBXIP基因真核表达载体pcDNA3 hbxip ,进行瞬时基因转染,将克隆有HBx基因的pCMV X (分别为1μg、2 μg和3μg)和pcDNA3 hbxip质粒分别和共转染至人H74 0 2肝癌细胞中(总体积分别为5 0 μl) .发现瞬时转染3μgpCMV X质粒后,肝癌细胞凋亡发生率为34 4 % ,肝癌细胞的细胞周期相关蛋白p2 7表达水平发生明显上调;与对照组相比,瞬时转染1μg、2 μg和3μg时,细胞周期蛋白D和细胞周期蛋白E的表达水平均发生明显上调,但随着HBX水平的增加细胞周期蛋白D和细胞周期蛋白E的表达水平发生明显下降;在稳定转染pCMV X质粒的H74 0 2 X肝癌细胞中无明显的细胞凋亡发生,研究发现p2 7的表达水平发生了明显下调,而细胞周期蛋白D和细胞周期蛋白E的表达水平发生了明显上调;当pcDNA3 hbxip质粒与pCMV X质粒进行共瞬时转染时,细胞凋亡发生率由pcDNA3质粒与pCMV X质粒共转染时的2 9 2 %下降为13 3% ,p2 7的表达水平发生了下调,但细胞周期蛋白D和细胞周期蛋白E的表达水平无明显变化.研究结果表明,瞬时转染一定剂量的x基因可导致肝癌细胞发生凋亡,细胞周期相关蛋白p2 7、细胞周期蛋白D和     

The NF2 tumor suppressor gene product, merlin, inhibits cell proliferation and cell cycle progression by repressing cyclin D1 expression

Inactivation of the NF2 tumor suppressor gene has been observed in certain benign and malignant tumors. Recent studies have demonstrated that merlin, the product of the NF2 gene, is regulated by Rac/PAK signaling. However, the mechanism by which merlin acts as a tumor suppressor has remained obscure. In this report, we show that adenovirus-mediated expression of merlin in NF2-deficient tumor cells inhibits cell proliferation and arrests cells at G1 phase, concomitant with decreased expression of cyclin D1, inhibition of CDK4 activity, and dephosphorylation of pRB. The effect of merlin on cell cycle progression was partially overridden by ectopic expression of cyclin D1. RNA interference experiments showed that silencing of the endogenous NF2 gene results in upregulation of cyclin D1 and S-phase entry. Furthermore, PAK1-stimulated cyclin D1 promoter activity was repressed by cotransfection of NF2, and PAK activity was inhibited by expression of merlin. Interestingly, the S518A mutant form of merlin, which is refractory to phosphorylation by PAK, was more efficient than the wild-type protein in inhibiting cell cycle progression and in repressing cyclin D1 promoter activity. Collectively, our data indicate that merlin exerts its antiproliferative effect, at least in part, via repression of PAK-induced cyclin D1 expression, suggesting a unifying mechanism by which merlin inactivation might contribute to the overgrowth seen in both noninvasive and malignant tumors.     

Frequent altered expression of fragile histidine triad protein in human colorectal adenomas

Fragile histidine triad (FHIT) gene is involved in deletions on the short arm of chromosome 3 in various human cancers. We found that 47% of colorectal adenomas, which is a higher frequency than that of K-ras, showed altered expression of the Fhit protein by Western blot analysis. The amount of Fhit protein was inversely correlated with the degree of dysplasia. Importantly, 27% of low-grade dysplastic adenomas showed altered expression of Fhit protein. Additionally, expression of human Fhit protein in human colon carcinoma cell line SW480 exhibited a marked inhibition of growth and rendered SW480 cells highly susceptible to undergo apoptosis compared with control cells. These findings suggest that altered expression of the FHIT gene is a quite early aberration in the development of colorectal tumors and that Fhit protein may act as a tumor suppressor.     

Ubc9-induced inhibition of diadenosine triphosphate hydrolase activity of the putative tumor suppressor protein Fhit

Fhit protein is the product of the putative tumor suppressor fragile histidine triad (FHIT) gene. The way by which Fhit exerts its antitumor activity remains largely unknown, although the Fhit-Ap3A complex is believed to be the native signaling form of Fhit. Here, we have shown that Fhit protein interacts with hUbc9, a recombinant human SUMO-1 conjugating enzyme, in an adenosine(5')triphospho(5')nucleoside (Ap3N)-dependent manner. Our experiments showed that the dinucleoside polyphosphate hydrolase activity of Fhit is suppressed by interacting with hUbc9 protein. In the presence of equimolar hUbc9 the Vmax and Km activity of Fhit was decreased by 35%. Analysis of Fhit kinetics in the presence of different fixed concentrations of Ubc9 showed that Ubc9 is an uncompetitive inhibitor. Including SUMO-1 protein in the assay neither affected the Fhit activity nor modified the effect of Ubc9 on Fhit kinetics. Our data suggest that hUbc9-induced inhibition of Fhit may result in an elongation of the Fhit-Ap3A signaling complex lifetime leading to alteration of its antitumor activity.     

脆性组氨酸三联体与复制蛋白A相互作用关键氨基酸残基的鉴定

目的：研究脆性组氨酸三联体（Fhit）对ATR/CHK1通路的影响,在确定Fhit与复制蛋白A（RPA）存在相互作用的基础上鉴定Fhit与RPA相互作用的关键氨基酸残基,为进一步研究Fhit特异的信号通路奠定基础。方法：构建一系列Fhit缺失突变体基因Fhit1～Fhit11及6种Fhit点突变体基因,将这些基因插入含GST基因的原核表达载体中,在大肠杆菌中表达并纯化GST-Fhit1～GST-Fhit11融合蛋白、突变体GST-FhitSIYEEL、GST-FhitIY、GST-FhitEL、GST-FhitF、GST-FhitA,以及GST-FhitD融合蛋白,用GST沉降技术研究Fhit与RPA相互作用的关键氨基酸残基。结果：Fhit蛋白第112～117（SIYEEL）残基可能是Fhit与RPA相互作用的关键区域,而第114（Y）残基可能是Fhit与RPA相互作用的关键氨基酸残基。结论：确定了Fhit与RPA相互作用的关键氨基酸残基,为阐明Fhit在维持基因组完整性方面的机理提供了线索。