c-Abl regulates p53 levels under normal and stress conditions by preventing its nuclear export and ubiquitination.

The p53 protein is subject to Mdm2-mediated degradation by the ubiquitin-proteasome pathway. This degradation requires interaction between p53 and Mdm2 and the subsequent ubiquitination and nuclear export of p53. Exposure of cells to DNA damage results in the stabilization of the p53 protein in the nucleus. However, the underlying mechanism of this effect is poorly defined. Here we demonstrate a key role for c-Abl in the nuclear accumulation of endogenous p53 in cells exposed to DNA damage. This effect of c-Abl is achieved by preventing the ubiquitination and nuclear export of p53 by Mdm2, or by human papillomavirus E6. c-Abl null cells fail to accumulate p53 efficiently following DNA damage. Reconstitution of these cells with physiological levels of c-Abl is sufficient to promote the normal response of p53 to DNA damage via nuclear retention. Our results help to explain how p53 is accumulated in the nucleus in response to DNA damage.

The CD44 receptor of lymphoma cells: structure-function relationships and mechanism of activation.

Migration of some tumor cells, and their lodgment in target organs, is dependent on the activation of cell surface CD44 receptor, usually detected by its ability to bind hyaluronic acid (HA) or other ligands. In an attempt to reveal the mechanism of tumor cell CD44 activation, we compared the physical and chemical properties of CD44 in nonactivated LB cell lymphoma with those in phorbol 12-myristate 13-acetate (PMA)-activated LB cells and of an LB cell subline (designated HA9) expressing constitutively-active CD44. In contrast to nonactivated LB cells, PMA-activated LB cells and HA9 cells displayed a CD44-dependent ability to bind HA. The ability of activated cell CD44 to bind HA was not dependent on microfilament or microtubule integrity or on changes in CD44 mobility on the membrane plane, indicating that the CD44 activation status is not associated with cytoskeleton function. Aside from the increased expression of CD44 on the surface of PMA-activated LB cells and HA9 cells, qualitative differences between the CD44 of nonactivated and activated LB cells were also detected: the CD44 of the activated lymphoma was (i) larger in molecular size, (ii) displayed a broader CD44 isoform repertoire, including a CD44 variant that binds HA, and (iii) its glycoprotein contained less sialic acid. Indeed, after removal of sialic acid from their cell surface by neuraminidase, LB cells acquired the ability to bind HA. However, a reduced dose of neuraminidase did not confer HA binding on LB cells, unless they were also activated by a low concentration of PMA, which by itself was ineffective. Similarly, under suboptimal conditions, a synergistic effect was obtained with tunicamycin and PMA: each one alone was ineffective but in combination they induced the acquisition of HA binding by the lymphoma cells, while their CD44 expression was not enhanced. Unveiling of the activation mechanism of CD44, by exposing the cells to PMA stimulation or to deglycosylation, is not only academically important, but it also has practical implications, as activated CD44 may be involved in the support of tumor progression.

The cellular response to p53: the decision between life and death.

The p53 tumor suppressor protein plays a crucial role in regulating cell growth following exposure to various stress stimuli. p53 induces either growth arrest, which prevents the replication of damaged DNA, or programmed cell death (apoptosis), which is important for eliminating defective cells. Whether the cell enters growth arrest or undergoes apoptosis, depends on the final integration of incoming signals with antagonistic effects on cell growth. Many factors affect the cellular response to activated p53. These include the cell type, the oncogenic status of the cell with emphasis on the Rb/E2F balance, the extracellular growth and survival stimuli, the intensity of the stress signals, the level of p53 expression and the interaction of p53 with specific proteins. p53 is regulated both at the levels of protein stability and biochemical activities. This complex regulation is mediated by a range of viral and cellular proteins. This review discusses this intriguing complexity which affects the cell response to p53 activation.

Mutations in serines 15 and 20 of human p53 impair its apoptotic activity.

Phosphorylation of the p53 tumor suppressor protein is likely to play an important role in regulating its activity. To study the regulatory role of potential phosphorylation sites within the N-terminal transactivation domain of human p53 (hp53), a series of p53 serine mutants were evaluated for transcriptional transactivation and sequence specific DNA binding. The role of these mutations in regulating p53-mediated growth suppression and programmed cell death was examined. This mutational analysis comprised serine residues located at positions 6, 9, 15, 20, 33 and 37 of human p53. Substitution of serine for alanine, either at individual residues or at all six residues together, did not affect the suppression of cell growth and cell transformation, or the ability to bind DNA specifically and to transactivate different promoters, nor did it alter p53 expression. However, the ability of p53 to induce apoptosis was impaired by specific serine substitutions. Mutations in all six N-terminal serines together reduced the apoptotic activity of p53 in H1299 cells by 50%. Analysis of individual mutants revealed that mutations in serine 15 and 20 are primarily responsible for this impairment. Our results suggest that these serines play a role in the regulation of p53-mediated apoptosis.

c-Abl neutralizes the inhibitory effect of Mdm2 on p53.

Upon exposure to stress signals, the p53 tumor suppressor protein is stabilized and induces growth suppression. p53 activities are efficiently inhibited by the Mdm2 oncoprotein through an autoregulatory feedback loop. In addition, Mdm2 promotes p53 degradation, thereby terminating its growth inhibitory signal. Hence, p53 exerts its effects during the interval between p53 activation and the subsequent inhibition by Mdm2. Modulation of this interval by regulatory proteins may determine the extent and duration of p53 activity. Recent studies have shown that the c-Abl protein-tyrosine kinase binds p53 and enhances its transcriptional activity. Here we provide an explanation for the cooperation between these proteins. We demonstrate that c-Abl increases the expression level of the p53 protein. The enhanced expression is achieved by inhibiting Mdm2-mediated degradation of p53. This provides a likely mechanistic explanation for the findings that c-Abl overcomes the inhibitory effects of Mdm2 on p53-mediated transcriptional activation and apoptosis. These results suggest that c-Abl modulates the time window within which p53 remains active. The ability of c-Abl to neutralize the inhibitory effects of Mdm2 on p53 may be important for its growth inhibitory function.

Calcium- and calmodulin-dependent PMA-activation of the CD44 adhesion molecule.

The ability of the CD44 adhesion molecule to interact with its ligand hyaluronic acid (HA) is tightly regulated. CD44-positive mouse LB lymphoma cells are unable to bind HA unless activated by the tumor promoter phorbol 12-myristate 13-acetate (PMA). PMA causes a dose-dependent increase in both CD44 expression level and HA-binding capacity, with the binding of HA observed only above a threshold amount of CD44 molecules. This induction of HA-binding as well as the increase in CD44 expression are prevented by cycloheximide, suggesting a requirement for new additional CD44 molecules on the cell surface and/or cooperating proteins. In the present study, we have investigated which of the signal transduction pathways activated by PMA leads to the increased CD44 expression with subsequent acquisition of HA-binding capacity. By comparing the influence of each inhibitory agent on PMA-activated LB lymphoma cells versus that on a constitutive HA-binder cell line derived from LB cells (designated HA9 cells), we could distinguish between an effect on the PMA-activation phase and a one on the HA-binding phase. Our data show that the PMA-induced HA-binding could not be blocked by agents inhibiting protein kinase C (PKC) (staurosporine, sphingosine, polymyxin B, quercetin) or genestein, an inhibitor of tyrosine protein kinases. However, this PMA response was strongly inhibited by calmodulin antagonists (chlorpromazine, trifluoperazine, W-7) and the calcium blocker verapamil. The calmodulin antagonists inhibited the PMA-induced increase in CD44 expression on LB cells, but had no influence on the ability of the constitutive HA-binder HA9 cell line to interact with HA, indicating an effect on the PMA induction phase rather than on the binding itself. Verapamil also blocked the PMA-induced increase in CD44 expression on LB cells, but in addition it slightly reduced the ability of the HA9 cells to bind HA without affecting their CD44 expression level. In conclusion, our data suggest that CD44 activation by PMA is calcium and calmodulin dependent, rather than mediated by protein kinase C.

CD44: structure, function, and association with the malignant process.

CD44 is a ubiquitous multistructural and multifunctional cells surface adhesion molecule involved in cell-cell and cell-matrix interactions. Twenty exons are involved in the genomic organization of this molecule. The first five and the last 5 exons are constant, whereas the 10 exons located between these regions are subjected to alternative splicing, resulting in the generation of a variable region. Differential utilization of the 10 variable region exons, as well as variations in N-glycosylation, O-glycosylation, and glycosaminoglycanation (by heparan sulfate or chondroitin sulfate), generate multiple isoforms (at least 20 are known) of different molecular sizes (85-230 kDa). The smallest CD44 molecule (85-95 kDa), which lacks the entire variable region, is standard CD44 (CD44s). As it is expressed mainly on cells of lymphohematopoietic origin, CD44s is also known as hematopoietic CD44 (CD44H). CD44s is a single-chain molecule composed of a distal extracellular domain (containing, the ligand-binding sites), a membrane-proximal region, a transmembrane-spanning domain, and a cytoplasmic tail. The molecular sequence (with the exception of the membrane-proximal region) displays high interspecies homology. After immunological activation, T lymphocytes and other leukocytes transiently upregulate CD44 isoforms expressing variant exons (designated CD44v). A CD44 isform containing the last 3 exon products of the variable region (CD44V8-10, also known as epithelial CD44 or CD44E), is preferentially expressed on epithelial cells. The longest CD44 isoform expressing in tandem eight exons of the variable region (CD44V3-10) was detected in keratinocytes. Hyaluronic acid (HA), an important component of the extracellular matrix (ECM), is the principal, but by no means the only, ligand of CD44. Other CD44 ligands include the ECM components collagen, fibronectin, laminin, and chondroitin sulfate. Mucosal addressin, serglycin, osteopontin, and the class II invariant chain (Ii) are additional, ECM-unrelated, ligands of the molecule. In many, but not in all cases, CD44 does not bind HA unless it is stimulated by phorbol esters, activated by agonistic anti-CD44 antibody, or deglycosylated (e.g., by tunicamycin). CD44 is a multifunctional receptor involved in cell-cell and cell-ECM interactions, cell traffic, lymph node homing, presentation of chemokines and growth factors to traveling cells, and transmission of growth signals. CD44 also participates in the uptake and intracellular degradation of HA, as well as in transmission of signals mediating hematopoiesis and apoptosis. Many cancer cell types as well as their metastases express high levels of CD44. Whereas some tumors, such as gliomas, exclusively express standard CD44, other neoplasms, including gastrointestinal cancer, bladder cancer, uterine cervical cancer, breast cancer and non-Hodgkin's lymphomas, also express CD44 variants. Hence CD44, particularly its variants, may be used as diagnostic or prognostic markers of at least some human malignant diseases. Furthermore, it has been shown in animal models that injection of reagents interfering with CD44-ligand interaction (e.g., CD44s- or CD44v-specific antibodies) inhibit local tumor growth and metastatic spread. These findings suggest that CD44 may confer a growth advantage on some neoplastic cells and, therefore, could be used as a target for cancer therapy. It is hoped that identification of CD44 variants expressed on cancer but not on normal cells will lead to the development of anti-CD44 reagents restricted to the neoplastic growth.

Differential H-2 antigen expression in teratocarcinoma-fibroblast hybrids.

Embryo-derived teratocarcinoma cells, like early embryonic cells, do not express the classical MHC class I antigens. The mRNAs for both the H-2 alpha chain and beta2-microglobulin are also undetectable in these cells. We observed that upon fusion of H-2-negative mouse P19 teratocarcinoma cells (H-2k allotype) with H-2-positive embryonic fibroblasts of C57BL/6 origin (H-2b allotype), teratocarcinoma-like cell hybrids were obtained which express the H-2Kb antigen derived from the embryonic fibroblasts, but not the H-2KkDk antigens of the teratocarcinoma. This finding demonstrates that the teratocarcinoma H-2 genes do not respond to the positive regulatory factors present in the hybrids. The H-2k allele was not lost during fusion, as shown by its expression in retinoic-acid-differentiated hybrids treated with interferon-gamma (10 U/ml, 4 days). H-2KkDk antigen expression could also be induced in the undifferentiated hybrids by treating the cells with the protein synthesis inhibitor cycloheximide (1-10 mu g/ml, 18 h), but not with the demethylating agent 5-azacytidine (5 mu M, 2-4 days). These data suggest the presence of a labile, negative regulating protein factor which selectively prevents the expression of the teratocarcinoma-derived H-2 antigens. When the level of this factor(s) is reduced, the teratocarcinoma H-2 genes are capable of responding to the positive regulatory factors.

Trophoblasts protect the inner cell mass from macrophage destruction.

Several mechanisms have been suggested to account for the survival of the semiallogeneic fetus in the maternal uterus. However, no data are available to explain how the blastocyst resists the high number of macrophages in the uterus at the time of implantation. The present study examines the in vitro development of murine 3.5-day-old syngeneic or semiallogeneic blastocysts in the presence of nonactivated or lipopolysaccharide (LPS)-activated macrophages. It was found that the in vitro development of blastocysts was undisturbed by the presence of nonactivated or LPS-activated macrophages. The outgrowing trophoblasts were not only nonadhesive to the macrophages but also repelled them actively, thus preventing them from reaching the inner cell mass (ICM). Removing the zona pellucida by use of pronase or killing the ICM by irradiation did not alter the repulsion of macrophages by the trophoblasts. On the other hand, removal of the trophectoderm by antibody and complement treatment rendered the macrophages adhesive and destructive to the ICM. Four of 15 ICM (27%) were destroyed by nonactivated macrophages, and all of the ICM (15/15) were destroyed by LPS-activated macrophages. It is noteworthy that the addition of colchicine, cytochalasin B, proteinase inhibitors, anti-transforming growth factor-beta (TGF beta) antibodies, and indomethacin had no effect on the repulsion of macrophages by the trophoblasts. Therefore, it seems that microtubular proteins, microfilaments, extracellular matrix-degrading enzymes, TGF beta, and prostaglandins are not involved in the repulsion process. These results indicate that trophoblasts protect the ICM from the destructive action of macrophages by a repulsion mechanism of an as yet unknown nature.

The unique killing of embryo-derived teratocarcinoma cells by nonactivated murine macrophages is not due to a lack of H-2 antigen expression.

It is well documented that activated macrophages, but not nonactivated ones, kill tumor cells in vitro without damaging normal cells. We, however, have previously shown that embryo-derived teratocarcinoma cells (F9, P19, PCC4) are efficiently killed by nonactivated macrophages as well as by activated ones. Whereas other tumor cells are killed extracellularly by macrophages, we found that F9 teratocarcinoma cells are phagocytosed alive by macrophages and subsequently killed intracellularly by a process dependent on intact lysosomal function. Neither the H-2 antigens nor the mRNAs for the alpha-chain and beta 2-microglobulin are detectable in embryo-derived teratocarcinoma cells. An obvious explanation for this unique killing is that the nonactivated macrophages recognize and kill these cells due to their lack of class I MHC antigen expression, assuming that class I MHC gene products on the target cells switch off the cytolytic machinery of nonactivated macrophages. Our present findings demonstrate that there is no correlation between H-2 antigen expression on tumor cells and their susceptibility to killing by macrophages. Retinoic acid-differentiated F9 cells and P19 cells expressing H-2 antigen after exposure to MAF (IFN-gamma) were sensitive to the killing by nonactivated macrophages. Hybrids that arose from fusion of P19 teratocarcinoma cells with embryonal normal fibroblasts (C57BL/6), which displayed the morphology of embryonal carcinoma stem cells and expressed H-2 antigens, were also sensitive to the killing by nonactivated macrophages. On the other hand, the H-2-negative testicular 402AX teratocarcinoma cells and K1735P melanoma cells were both resistant to the killing by nonactivated macrophages. We concluded that the unique killing of embryo-derived teratocarcinoma cells by nonactivated murine macrophages is not related to a lack of H-2 antigen expression.

Engulfment and intracellular killing of F9 teratocarcinoma cells by non-activated murine macrophages.

Activated macrophages kill several types of tumor cells in vitro, whereas non-activated macrophages lack this capacity. We, however, observed that non-activated macrophages efficiently kill F9 teratocarcinoma as well as other teratocarcinoma cell lines. Dexamethasone, a glucocorticoid known to prevent macrophage activation, did not perturb the killing of F9 teratocarcinoma cells. Neither tumor necrosis factor alpha, nor the reactive oxygen intermediates, i.e. hydrogen peroxide, superoxide anion, and hydroxyl radical, nor serine proteases participated in this killing, shown by employing various agents which interfere with their production, secretion, or function. Using acridine orange/ethidium bromide vitality staining, the F9 teratocarcinoma cells were shown to be phagocytized alive by macrophages and subsequently killed intracellularly. Intact lysosomal function is required for the killing of F9 cells, as the lysosomotropic drugs chloroquine and ammonium chloride markedly inhibited this killing without perturbing their engulfment. The signal transduction pathway induced in the macrophages upon interaction with F9 teratocarcinoma cells seems to differ from that induced by macrophage activation. Neither the protein kinase C inhibitors polymyxin B and H-7 [1-(5-isoquinolinylsulfonyl)-2-methyl piperazine] nor the protein kinase C activator phorbol 12-myristate-13-acetate affected the killing of F9 cells. However, chlorpromazine (a powerful inhibitor of calmodulin), dibutyryl cAMP (a cAMP analog), and prostaglandin E2 inhibited the macrophage-mediated killing of F9 cells. In vivo studies indicate that an increased number of macrophages at the F9 tumor inoculation site (the peritoneal cavity) as a result of elicitation by thioglycollate prevents F9 tumor development. Our findings indicate that non-activated macrophages kill teratocarcinoma cells using a mechanism which differs from that employed by activated macrophages in the killing of other tumor cells.