ALEX1 suppresses colony formation ability of human colorectal carcinoma cell lines.

Arm protein lost in epithelial cancers, on chromosome X (ALEX; also known as armadillo repeat containing, X-linked [ARMCX]) is a novel subgroup within the armadillo (ARM) family, which has several ARM repeat domains. The biological function of classical ARM family members such as ß-catenin is well understood, but that of the ALEX/ARMCX family members is largely unknown. Here we evaluate the effects of ALEX1 overexpression on in vitro colony formation ability and expression of ALEX1 mRNA in human colorectal tumor. Overexpression of ALEX1 suppressed the anchorage-dependent and -independent colony formation of human colorectal carcinoma cell lines by the study of stable clones of HCT116 cells expressing ALEX1 protein. Bisulfite genomic sequencing revealed that the promoter region of ALEX1 gene was highly methylated in both HCT116 and SW480 cells in comparison with PANC-1 and MCF-7 cells, which express endogenous ALEX1 mRNA, indicating the capability of promoter methylation to silence ALEX1 gene in HCT116 and SW480 cells. Our current findings suggest that overexpression of ALEX1 play a negative role in human colorectal tumorigenesis.

Reconstruction system of rat lymphatic tracts after total iliac lymphadenectomy.

BACKGROUND/AIMS: The lymphatic network is capable of reconstruction after the regional lymphadenectomy; however, the biological reconstruction system has not been fully elucidated. Our aim is to evaluate the reconstruction system after bilateral iliac lymphadenectomy using rat models and to establish and characterize rat lymphatic endothelial cells (rLECs) from the reconstructed tracts, compared with those from pre-existing vessels. METHODOLOGY: Under general anesthesia, we excised the dyed bilateral lymphatic vessels. We reopened the treated rats again after 2-10 weeks to observe the reconstruction system. We isolated and cultured rLECs from afferent, efferent and reconstructed lymphatic vessels. We characterized them morphologically and biologically, and examined their activity of proliferation, migration and invasion. RESULTS: We demonstrated that lymph vessels were reconstructed at 4-10 weeks at the site of surgical removal of iliac lymphatic channels, which occurred mainly at the left side of abdomen of the rat (86% on the left side). Isolated cells were all confirmed to be rLECs by expression of lymphatic vessel-specific markers. Proliferative activity of reconstructed rLECs was significantly higher than the other two strains of rLECs. CONCLUSIONS: We first established the reconstruction system after rat total iliac lymphadenectomy and characterized rLECs from the three strains of lymphatic vessels.

Human Arm protein lost in epithelial cancers, on chromosome X 1 (ALEX1) gene is transcriptionally regulated by CREB and Wnt/beta-catenin signaling.

The aberrant activation of Wnt signaling is a key process in colorectal tumorigenesis. Canonical Wnt signaling controls transcription of target genes via beta-catenin and T-cell factor/lymphoid enhancer factor family transcription factor complex. Arm protein lost in epithelial cancers, on chromosome X 1 (ALEX1) is a novel member of the Armadillo family which has two Armadillo repeats as opposed to more than six repeats in the classical Armadillo family members. Here we examine cis-regulatory elements and trans-acting factors involved in the transcriptional regulation of the ALEX1 gene. Site-directed mutations of a cyclic AMP response element (CRE) and an E-box impaired the basal activity of human ALEX1 promoter in colorectal and pancreatic cancer cell lines. Moreover, overexpression of CRE-binding protein (CREB) increased the ALEX1 promoter activity in these cell lines, whereas knockdown of CREB expression decreased the expression level of ALEX1 mRNA. Interestingly, luciferase reporter analysis and quantitative real-time RT-PCR demonstrated that the ALEX1 promoter was up-regulated in a CRE-dependent manner by continuous activation of Wnt/beta-catenin signaling induced by a glycogen synthase kinase-3 inhibitor and overexpression of beta-catenin. These results indicate that the CRE and E-box sites are essential cis-regulatory elements for ALEX1 promoter activity, and ALEX1 expression is regulated by CREB and Wntk/beta-catenin signaling.

DA-Raf1, a competent intrinsic dominant-negative antagonist of the Ras-ERK pathway, is required for myogenic differentiation.

Ras activates Raf, leading to the extracellular-regulated kinase (ERK)-mitogen-activated protein kinase pathway, which is involved in a variety of cellular, physiological, and pathological responses. Thus, regulators of this Ras-Raf interaction play crucial roles in these responses. In this study, we report a novel regulator of the Ras-Raf interaction named DA-Raf1. DA-Raf1 is a splicing isoform of A-Raf with a wider tissue distribution than A-Raf. It contains the Ras-binding domain but lacks the kinase domain, which is responsible for activation of the ERK pathway. As inferred from its structure, DA-Raf1 bound to activated Ras as well as M-Ras and interfered with the ERK pathway. The Ras-ERK pathway is essential for the negative regulation of myogenic differentiation induced by growth factors. DA-Raf1 served as a positive regulator of myogenic differentiation by inducing cell cycle arrest, the expression of myogenin and other muscle-specific proteins, and myotube formation. These results imply that DA-Raf1 is the first identified competent, intrinsic, dominant-negative antagonist of the Ras-ERK pathway.

von Willebrand factor type D domain mutant of SVS-1/SUSD2, vWD(m), induces apoptosis in HeLa cells.

SVS-1/SUSD2 is a novel gene, which inhibits growth and reverses tumorigenic phenotypes of cancer cells in vitro. Here we report identification of a mutant of SVS-1, designated SVS-1-vWD(m), in which conserved amino acids GLLG at positions 591-594 in von Willebrand factor type D (vWD) domain are replaced by AAAA. As observed by laser confocal microscope, intracellular localization of the mutant protein has changed such that both the N-terminus and the C-terminus of SVS-1-vWD(m) were localized in the inner surface of the plasma membrane, whereas the N-terminus of SVS-1 was localized in the outer surface of the plasma membrane. Additionally, SVS-1-vWD(m) was processed much less efficiently and in a slightly different manner. In in vitro studies, adenovirus-mediated transduction of the SVS-1-vWD(m)gene induced growth suppression of HeLa cells in a dose-dependent manner, as the wild-type gene and inhibition of anchorage-independent growth. Of great interest is the finding that the mutant protein, vWD(m), but not the wild-type one induced apoptosis, as observed by nuclear as well as DNA fragmentation. Activation of caspase-3 and -9, but not caspase-8 or -12, was also demonstrated in vWD(m)-expressing cells. An inhibition of Akt phosphorylation, a major survival signaling component, also occurred in vWD(m)-expressing HeLa cells. Together these data suggest that vWD(m) induces apoptosis by inactivation of survival signaling component Akt and activation of caspase cascade (mitochondrial pathway) in HeLa cells. We propose SVS-1-vWD(m)as an alternative gene for use in developing new therapeutic strategies for the treatment of cancer.

Isolation of a novel mouse gene, mSVS-1/SUSD2, reversing tumorigenic phenotypes of cancer cells in vitro.

We report isolation of a novel tumor-reversing gene, tentatively named SVS-1, encoding a protein of 820 amino acids with localization on the plasma membrane as a type I transmembrane protein. The gene was found among those downregulated in the activated oncogene-v-K-ras-transformed NIH3T3 cells, Ki3T3, with tumorigenic phenotype. SVS-1 protein harbors several functional domains inherent to adhesion molecules. Histochemical staining of mouse tissues using antibody raised against the protein showed the expression of the protein in restricted regions and cells, for example, strongly positive in apical membranes of epithelial cells in renal tubules and bronchial tubes. The protein inducibly expressed in human fibrosarcoma HT1080 cells and cervical carcinoma HeLa cells was found to be localized primarily on the plasma membrane, as stained with antibodies against FLAG tag in the N-terminus and against the C-terminal peptide of the protein. Expression of the protein in cells induced a variety of biological effects on cancer cells: detachment from the substratum and aggregation of cells and growth inhibition in HeLa cells, but no inhibition in non-tumorigenic mouse NIH3T3 cells. Inhibition of clonogenicity, anchorage-independent growth, migration and invasion through Matrigel was also observed. Taken together these results suggest that the SVS-1 gene is a possible tumor-reversing gene.

Leptosins isolated from marine fungus Leptoshaeria species inhibit DNA topoisomerases I and/or II and induce apoptosis by inactivation of Akt/protein kinase B.

DNA topoisomerases (topo) I and II are molecular targets of several potent anticancer agents. Thus, inhibitors of these enzymes are potential candidates or model compounds for anticancer drugs. Leptosins (Leps) F and C, indole derivatives, were isolated from a marine fungus, Leptoshaeria sp. as cytotoxic substances. In vitro cytotoxic effects of Lep were measured using 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide-based viability assay. Lep F inhibited the activity of topos I and II, whereas Lep C inhibited topo I in vitro. Interestingly both of the compounds were found to be catalytic inhibitors of topo I, as evidenced by the lack of stabilization of reaction intermediate cleavable complex (CC), as camptothecin (CPT) does stabilize. Furthermore, Lep C inhibited the CC stabilization induced by CPT in vitro. In vivo band depletion analysis demonstrated that Lep C likewise appeared not to stabilize CC, and inhibited CC formation by CPT, indicating that Lep C is also a catalytic inhibitor of topo I in vivo. Cell cycle analysis of Lep C-treated cells showed that Lep C appeared to inhibit the progress of cells from G(1) to S phase. Lep C induced apoptosis in RPMI8402 cells, as revealed by the accumulation of cells in sub-G(1) phase, activation of caspase-3 and the nucleosomal degradation of chromosomal DNA. Furthermore, Leps F and C inhibited the Akt pathway, as demonstrated by dose-dependent and time-dependent dephosphorylation of Akt (Ser473). Our study shows that Leps are a group of anticancer chemotherapeutic agents with single or dual catalytic inhibitory activities against topos I and II.

Ribozymes targeting serine/threonine kinase Akt1 sensitize cells to anticancer drugs.

The serine/threonine kinase Akt is a key component of the cellular signaling pathway for survival and drug-resistance in cancer cells. In the present study we confirmed this view by expressing an antagonist of Akt, a dominant negative form of Akt, in HCT116 colon carcinoma cells and observing apoptosis induction in cells in which expression of the mutant protein had been induced. Three isoforms of Akt have been found: Akt1/PKBalpha, Akt2/PKBbeta and Akt3/PKBgamma. However, the function of individual isoforms with respect to tumorigenicity and drug-resistance of cancer cells is largely unknown. We designed ribozymes targeting the Akt1 protein in mammalian cells. Our data indicate that Akt1 ribozymes downregulate Akt1 expression to less than half that of control cells. Downregulation of Akt1 expression appears to sensitize HEK293 and HeLa cells to typical chemotherapeutic agents. However, Akt1 ribozymes had little effect on the proliferative activity of the cells. Thus, Akt as a whole and even just the Akt1 isozyme is an excellent target for chemotherapy. We further suggest a synergistic effect for combination therapy targeting Akt and other vital molecules such as tubulins, topoisomerases and protein kinases.

Interaction between glucose-regulated destruction domain of DNA topoisomerase IIalpha and MPN domain of Jab1/CSN5.

DNA topoisomerase (topo) IIalpha, an essential enzyme for cell proliferation, is targeted to a proteasome-dependent degradation pathway when human tumor cells are glucose-starved. Here we show that the topo IIalpha destabilization depends on the newly identified domain, GRDD (glucose-regulated destruction domain), which was mapped to the N-terminal 70-170 amino acid sequence. Indeed, the deletion of GRDD conferred a stable feature on topo IIalpha, whereas the fusion of GRDD rendered green fluorescent protein unstable under glucose starvation conditions. Nuclear localization was a prerequisite for GRDD function, because the inhibition of nuclear translocation resulted in the suppression of GRDD-mediated topo IIalpha degradation. Further, GRDD was identified as an interactive domain for Jab1/CSN5, which promoted the degradation of topo IIalpha in a manner dependent on the MPN (Mpr1p/Prd1p N terminus) domain. Depleting Jab1/CSN5 by antisense oligonucleotide and treating cells with the CSN-associated kinase inhibitor, curcumin, inhibited topo IIalpha degradation induced by glucose starvation. These findings demonstrate that GRDD can act as a stress-activated degron for regulating topo IIalpha stability, possibly through interaction with the MPN domain of Jab1/CSN5.

[Screening of DNA topoisomerase inhibitors].

It has been established that etoposide (ETP), adriamycin (doxorubicin: DOX) and irinotecan (CPT-11), efficacious antitumor drugs widely used in clinics, target DNA topoisomerases (topo) in vivo. The present report attempts to explain why topos are the good targets of anticancer drugs from the point of view of enzymology of the enzymes and cell cycle behavior of tumor cells. Thus, many candidate anticancer drugs targeting topos are being screened, and preclinical and clinical studies thereof are being conducted world-wide and in Japan.

Inhibition of chromosome separation in fertilized starfish eggs by kalihinol F, a topoisomerase I inhibitor obtained from a marine sponge.

Kalihinol F, a naturally occurring diterpene from a marine sponge, Acanthella sp., inhibited chromosome separation in fertilized starfish (Asterina pectinifera) eggs but allows the first cleavage to occur, thereby forming unseparated metaphase chromosomes which were elongated between the two daughter cells. The chromosomes were eventually torn off in the embryonic cells. Most of the cells gradually lost the chromosomes during the cell cycle progression. The embryonic development halted at the morula stage just before the onset of blastulation. The mitotic failure occurred when kalihinol F was applied to a fertilized egg during the second meiotic process, but not after the completion of the second meiotic division. Kalihinol F inhibited topoisomerase I activity in vitro, but had no effects on activities of DNA polymerases alpha, beta, and gamma, and of topoisomerase II. These results suggest that the topoisomerase I plays an essential role in meiosis II in this species.

Inhibition of DNA topoisomerases I and II, and growth inhibition of human cancer cell lines by a marine microalgal polysaccharide.

We have previously reported purification of an extracellular polysaccharide GA3P, D-galactan sulfate associated with L-(+)-lactic acid, produced by a toxic marine microalga Dinoflagellate Gymnodinium sp. A(3) (GA3), and induction thereby of apoptosis on human myeloid leukemia K562 cells. In the present report, we show that the GA3P is a potent inhibitor of DNA topoisomerase (topo) I and topo II, irrespective of the presence or absence of the lactate group. Dextran sulfate also showed similar level of inhibition of topo I and topo II. We also demonstrated that, unlike camptothecin (CPT) or teniposide (VM-26), the inhibition of topo I or topo II by the polysaccharide does not involve accumulation of DNA-topo I/II cleavable complexes, clearly showing that they are not topo poisons but catalytic inhibitors with dual activity. Furthermore, the polysaccharide, when added to the reaction mixture with CPT or VM-26, inhibited stabilization of cleavable complex induced by the latter compounds. In addition, when added to the reaction mixture after the formation of the cleavable complexes by topo poisons, CPT for topo I and VM-26 for topo II, either GA3P or dextran sulfate diminished the amount of the complexes already accumulated, i.e. reversal of the reaction. These results suggest that the polysaccharides bind to the enzymes with high affinities, and that, as for topo I/II inhibition, the GA3P shares a common mechanism with dextran sulfate. As examined in vitro with a human cancer cell line panel, GA3P exhibited significant cytotoxicity against a variety of cancer cells. These findings show that the polysaccharide GA3P would prove to be a potential anticancer chemotherapeutic agent with dual activity of topo I and topo II catalytic inhibition.

Down-regulation of Bcl-2-interacting protein BAG-1 confers resistance to anti-cancer drugs.

BAG-1 was originally identified as a binding partner of anti-apoptotic factor Bcl-2 [Takayama et al., Cell 80 (1995) 279-284]. Exogenous expression of BAG-1 was reported to confer cells resistance to several stresses [Chen et al., Oncogene 21 (2002) 7050]. We have obtained human cervical cancer HeLa cells with down-regulated BAG-1 levels by using a highly specific and efficient RNA interference approach. Surprisingly, cells with down-regulated BAG-1 exhibited significantly lower sensitivity against several anti-cancer drugs than parental cells expressing normal levels of the protein. Furthermore, growth rate of the cells was reduced when BAG-1 was down-regulated. Activity of ERK pathway appeared to be decreased in BAG-1 down-regulated cells, as shown by the reduced phosphorylation of ERK1/2 proteins. Taken together resistance against anti-cancer drugs acquired by BAG-1 down-regulated cells may well be accounted for by the retardation of cell cycle progression, implicating the importance of BAG-1 in cell growth regulation.

Inhibition of DNA topoisomerases II and/or I by pyrazolo[1,5-a]indole derivatives and their growth inhibitory activities.

DNA topoisomerases (topos) I and II are molecular targets of several potent anticancer agents. Thus inhibitors of these enzymes are potential candidates or model compounds for anticancer drugs. We found some of the totally synthetic pyrazolo[1,5-a]indole derivatives, GS-2, -3, and -4, to be strong inhibitors of topo II, and GS-5 was found to be a dual inhibitor of topos I and II (IC(50) values were in the range of 10-30 microM). Because of the DNA-intercalating activity of these compounds affecting supercoil structure of closed circular DNA, the method of evaluation of topo I inhibition designed for such compounds by Pommier et al. (Nucleic Acids Res 15:6713-6731, 1987) was employed. Results showed that only GS-5 with a hydroxyl group at position C-6 was found to be a strong inhibitor of topo I with an IC(50) of approximately 10 microM. Inhibition of topo I and/or topo II by these compounds does not involve significant accumulation of DNA-topo I/II cleavable complexes, demonstrating that they are not topo poisons but catalytic inhibitors. In the "band depletion" analysis for in vivo targeting of topo I and II, these compounds were shown to suppress depletion of intracellular free enzymes by the topo poisons etoposide and/or camptothecin, indicating that they do target topo I and/or II in living cells. These compounds also exhibit moderate to strong growth-inhibitory activity in panels of human cancer cell lines. This study shows pyrazolo[1,5-a]indole derivatives to be a novel group of anticancer chemotherapeutic agents with single or dual catalytic inhibitory activities against topo I and topo II.