Emma Shtivelman

A Role for PI 3-Kinase and PKB Activity in the G2/M Phase of the Cell Cycle

The role of the PI 3-kinase cascade in regulation of cell growth is well established [1]. PKB (protein kinase B) is a key downstream effector of the PI 3-kinase pathway and is best known for its antiapoptotic effects [2,3] and the role it plays in initiation of S phase [4]. Here, we show that PKB activity is high in the G2/M phase of the cell cycle in epithelial cells. Inhibition of the PI 3-kinase pathway in MDCK cells induces apoptosis at the G2/M transition, prevents activation of cyclin B-associated kinase, and prohibits entry of the surviving cells into mitosis. All of these consequences of the inhibition of PI 3-kinase are relieved by expression of a constitutively active form of PKB (caPKB), indicating that PKB plays a role in regulation of the G2/M phase. Inhibition of PI 3-kinase results in activation of Chk1, whereas caPKB inhibits the ability of Chk1 to become activated in response to treatment with hydroxyurea. Preliminary data show that PKB phosphorylates the Chk1 polypeptide in vitro on serine 280. These results not only implicate PKB activity in transition through the G2/M stage of the cell cycle, but they also suggest the existence of crosstalk between the PI 3-kinase pathway and the key regulators of the DNA damage checkpoint machinery.

Protein kinase B phosphorylates AHNAK and regulates its subcellular localization

AHNAK is a ubiquitously expressed giant phosphoprotein that was initially identified as a gene product subject to transcriptional repression in neuroblastoma. AHNAK is predominantly nuclear in cells of nonepithelial origin, but is cytoplasmic or associated with plasma membrane in epithelial cells. In this study we show that the extranuclear localization of AHNAK in epithelial cells depends on the formation of cell–cell contacts. We show that AHNAK is a phosphorylation substrate of protein kinase B (PKB) in vitro and in vivo. Nuclear exclusion of AHNAK is mediated through a nuclear export signal (NES) in a manner that depends on the phosphorylation of serine 5535 of AHNAK by PKB, a process that also plays a major role in determining extranuclear localization of AHNAK. AHNAK is a new PKB substrate whose function, though unknown, is likely to be regulated by its localization, which is in turn regulated by PKB.

Inhibition of Chk1 by activated PKB/Akt

We have shown recently that DNA damage effector kinase Chk1 is phosphorylated invitro by protein kinase B/Akt (PKB/Akt) on serine 280. Activation of Chk1 by DNAdamage in vivo is suppressed in presence of activated PKB. In this study we show thatChk1 is phosphorylated by PKB in vivo, and that increased phosphorylation by PKB onserine 280 correlates with impairment of Chk1 activation by DNA damage. Our resultsindicate a likely mechanism for the negative effects that phosphorylation of serine 280has on activation of Chk1. The Chk1 protein phosphorylated by PKB on serine 280 doesnot enter into protein complexes after replication arrest. Moreover, Chk1 phosphorylatedby PKB fails to undergo activating phosphorylation on serine 345 by ATM/ATR.Phosphorylation by ATM/ATR and association with other checkpoint proteins areessential steps in activation of Chk1. Inhibition of these steps provides a plausibleexplanation for the observed attenuation of Chk1 activation by activated PKB after DNAdamage.

The PVT gene frequently amplifies with MYC in tumor cells.

The line of human colon carcinoma cells known as COLO320-DM contains an amplified and abnormal allele of the proto-oncogene MYC (DMMYC). Exon 1 and most of intron 1 of MYC have been displaced from DMMYC by a rearrangement of DNA. The RNA transcribed from DMMYC is a chimera that begins with an ectopic sequence of 176 nucleotides and then continues with exons 2 and 3 of MYC. The template for the ectopic sequence represents exon 1 of a gene known as PVT, which lies 50 kilobase pairs downstream of MYC. We encountered three abnormal configurations of MYC and PVT in the cell lines analyzed here: (i) amplification of the genes, accompanied by insertion of exon 1 and an undetermined additional portion of PVT within intron 1 of MYC to create DMMYC; (ii) selective deletion of exon 1 of PVT from amplified DNA that contains downstream portions of PVT and an intact allele of MYC; and (iii) coamplification of MYC and exon 1 of PVT, but not of downstream portions of PVT. We conclude that part or all of PVT is frequently amplified with MYC and that intron 1 of PVT represents a preferred boundary for amplification affecting MYC.

Effects of translocations on transcription from PVT

We have previously described a transcription unit on human chromosome 8, designated as PVT, that is consistently disrupted by the minority forms of translocations [t(2;8) and t(8;22)] in Burkitts lymphoma. PVT begins 57 kilobase pairs downstream of the proto-oncogene MYC and is more than 200 kilobase pairs in length. In order to explore the pathogenic impact of translocations affecting PVT, we have characterized further the structure and transcription of the locus. In normal cells, PVT is transcribed into a variety of RNAs, the diversity of which remains unexplained. Alleles of PVT affected by translocations give rise to additional RNAs. These RNAs arise from a fusion of the first exon of PVT on chromosome 8 to the constant region of an immunoglobulin light chain on either chromosome 2 or chromosome 22. We have found no evidence that any of the normal or abnormal transcripts of PVT give rise to a protein. Our results suggest that the pathogenic effects of the variant translocations in Burkitts lymphoma are not executed by a gene situated in a vicinity of the chromosomal breakpoints. Instead, our data leave open the possibility that the effects of the translocations may be mediated by activation of the relatively distant MYC gene.

Inhibition of nuclear import by the proapoptotic protein CC3

ABSTRACT We report here that the normal cellular protein CC3/TIP30, when in excess, inhibits nuclear import in vitro and in vivo. CC3 binds directly to the karyopherins of the importin β family in a RanGTP-insensitive manner and associates with nucleoporins in vivo. CC3 inhibits the nuclear import of proteins possessing either the classical nuclear localization signal or the M9 signal recognized by transportin. CC3 also inhibits nuclear translocation of transportin itself. Cells modified to express higher levels of CC3 have a slower rate of nuclear import and, as described earlier, show an increased sensitivity to death signals. A mutant CC3 protein lacking proapoptotic activity has a lower affinity for transportin, is displaced from it by RanGTP, and fails to inhibit nuclear import in vitro and in vivo. Together, our results support a correlation between the ability of CC3 to form a RanGTP-resistant complex with importins, inhibit nuclear import, and induce apoptosis. Significantly, a dominant-negative form of importin β1 shown previously to inhibit multiple transport pathways induces rapid cell death, strongly indicating that inhibition of nuclear transport serves as a potent apoptotic signal.

Molecular mechanisms underlying selective cytotoxic activity of BZL101, an extract of Scutellaria barbata, towards breast cancer cells.

We studied the mechanism of the cytotoxic activity of BZL101, an aqueous extract from the herb Scutellaria barbata D. Don, which is currently in phase II clinical trial in patients with advanced breast cancer. The phase I trial showed favorable toxicity profile and promising efficacy. We report here that BZL101 induces cell death in breast cancer cells but not in non-transformed mammary epithelial cells. This selective cytotoxicity is based on strong induction by BZL101 of reactive oxygen species (ROS) in tumor cells. As a consequence, BZL101 treated cancer cells develop extensive oxidative DNA damage and succumb to necrotic death. Data from the expression profiling of cells treated with BZL101 are strongly supportive of a death pathway that involves oxidative stress, DNA damage and activation of death-promoting genes. In breast cancer cells oxidative damage induced by BZL101 leads to the hyperactivation of poly (ADP-ribose) polymerase (PARP), followed by a sustained decrease in levels of NAD and depletion of ATP, neither of which are observed in non-transformed cells. The hyperactivation of PARP is instrumental in the necrotic death program induced by BZL101, because inhibition of PARP results in suppression of necrosis and activation of the apoptotic death program. BZL101 treatment leads to the inhibition of glycolysis selectively in tumor cells, evident from the decrease in the enzymatic activities within the glycolytic pathway and the inhibition of lactate production. Because tumor cells frequently rely on glycolysis for energy production, the observed inhibition of glycolysis is likely a key factor in the energetic collapse and necrotic death that occurs selectively in breast cancer cells. The promising selectivity of BZL101 towards cancer cells is based on metabolic differences between highly glycolytic tumor cells and normal cells.

CC3/TIP30 regulates metabolic adaptation of tumor cells to glucose limitation

CC3/TIP30 is a metastasis and tumor suppressor, with reduced or absent expression in a variety of aggressive tumors. Overexpression of CC3 in tumor cells predisposes them to apoptosis in response to different death signals. We found that silencing of CC3 expression does not increase apoptotic resistance of cells. However, it strongly improves survival of tumor cells in response to glucose limitation. HeLa cells with silenced CC3 survive long-term in low glucose, and, in comparison to control HeLa cells, show superior metabolic adaptation to glucose limitation. First, unlike the parental HeLa cells, HeLa with silenced CC3 activate and maintain high levels of mitochondrial respiration that is critical for their ability to thrive in low glucose. Second, silencing of CC3 leads to higher expression levels of mitochondrial proteins in respiration complexes when cells are continuously cultured in limiting glucose. Third, HeLa cells with silenced CC3 maintain higher levels of c-MYC and the M2 isoform of pyruvate kinase in low glucose, contributing to more efficient glycolysis. Fourth, HeLa cells with silenced CC3 fail to fully activate AMPK in response to glucose limitation. Inhibition of AMPK, either pharmacologic or via siRNA, protects control HeLa cells from death in low glucose. The metabolic flexibility acquired by cells after silencing of CC3 could be directly relevant to the development of metastatic and aggressive human tumors that frequently have low or absent expression of CC3.

Multiple developmental roles of Ahnak are suggested by localization to sites of placentation and neural plate fusion in the mouse conceptus

Ahnak is a gigantic (700 kD) phosphoprotein with a unique structure whose expression and cellular localization are dynamically regulated during cell cycle progression. Here, we report that Ahnak is localized to sites of major morphogenesis during mouse placentation and neurulation. Ahnak was found in: (i) derivatives of trophectoderm, including chorionic ectoderm prior to and during union with the ectoplacental cone, presumptive syncytiotrophoblast cells in the chorionic labyrinth, and giant cells at the trophoblast-uterine interface; (ii) the allantois prior to, during, and after union with the chorion; and (iii) the tips of the neural plate during formation of the neural tube. On the basis of these observations, we suggest that Ahnak may play heretofore unrecognized roles in tissue union during normal mouse development.

SCID-hu mice for the study of human cancer metastasis

Abstract Cancer metastasis involves dynamic and multistep in vivo processes. While generation of metastatic clones requires genetic alterations in cancer cells, subsequent selection of the clones is heavily influenced by interactions with the surrounding tissue microenvironment. To reproduce the complex cellular interactions that occur in human patients is, however, difficult, and has not been achieved using currently available in vitro systems or conventional animal models. The SCID-hu mouse is generated by surgical implantation of human fetal tissues into mutant mice of the severe combined immunodeficient (SCID) phenotype. The unique feature of this model is that the implanted human tissues maintain their normal architecture and function. Therefore implanted human tissues will provide relevant microenvironments for the growth and metastasis of human cancer cells. The SCID-hu mouse model, which was specifically designed for the study of human cancer biology, enables experimental investigation of cellular events involved in cancer metastasis on the basis of interactions between human cancer cells and the human tissue microenvironment. It has been demonstrated that various types of human cancer cell lines generate tumors in implanted human bone marrow and lung, organs frequently involved in metastasis in patients, upon intravenous inoculation. Tumorigenic activity in SCID-hu mice faithfully reflects the clinical features of the original cancer. Tumor formation and selection of high tumorigenic variants occur in a species-specific manner. Furthermore, it was shown that metastatic tumor formation is regulated by both cancer cells and conditions in the host organs. Conditioning of animals by either whole-body irradiation or interleukin 1α treatment prior to cancer cell inoculation induced metastatic tumor formation by certain small cell lung cancer (SCLC) cell lines specifically in human bone marrow. A novel gene has been identified by comparing gene expression profiles between high and low tumorigenic SCLC cells in human lung. This gene is preferentially expressed in low metastatic lines, and transfection of the gene into highly metastatic cells results in suppression of metastasis. Recent studies have shown that the gene product is involved in the apoptosis induction pathway. Collectively, our results indicate that the SCID-hu mouse will serve as a unique platform technology with which to investigate cellular events involved in human cancer metastasis, as well as to identify genes playing important roles in the growth and metastasis of human cancer, in the context of interactions between human cancer cells and human tissue environments.