Marion M. Nau

p53: a transdominant regulator of transcription whose function is ablated by mutations occurring in human cancer.

Gal4‐p53 fusion constructs demonstrate that wild type p53 is a potent transactivator in human lung cancer cells with the transactivation domain for p53 residing in amino acids 1–42. Strikingly, a variety of lung cancer derived p53 mutations occurring outside this domain disrupt this activity. Temperature sensitive conformational shifts of p53 mutant proteins to the wild type form exist and, with a temperature downshift, several mutants become transcriptionally active. Wild type p53 protein is known to form oligomers with mutant p53 and cotransfection of wild type and mutant genes shows that p53 acts in a transdominant manner that is independent of the DNA binding specificity. Transcription is either increased or decreased depending on whether the wild type is more or less abundant than the mutant form. Finally, lung cancers differ in their ability to support the transactivation related functions, providing evidence of other abnormalities of the p53 system in human cancer.

TRAIL induces apoptosis in triple-negative breast cancer cells with a mesenchymal phenotype

Tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) induces apoptosis in some but not all breast cancer cell lines. Breast cancers can be divided into those which express the estrogen (ER) and progesterone (PR) receptors, those with HER-2 amplification, and those without expression of ER, PR, or HER-2 amplification (referred to as basal or triple-negative breast cancer). We tested a panel of 20 breast cancer cell lines representing the different types of breast cancer to evaluate if the molecular phenotype of the breast cancer cells determined their response to TRAIL. The most striking finding was that eight of eleven triple-negative cell lines are sensitive to TRAIL-mediated apoptosis. The eight TRAIL-sensitive triple-negative cell lines have a mesenchymal phenotype while the three TRAIL-resistant triple-negative cell lines have an epithelial phenotype. Two of five cell lines with HER-2 amplification were sensitive to TRAIL and none of the five ER positive cell lines were sensitive. RNAi-mediated knockdown of TRAIL receptor expression demonstrated that TRAIL Receptor 2 (TRAIL-R2) mediates the effects of TRAIL, even when both TRAIL-R1 and TRAIL-R2 are expressed. Finally, inhibition of EGFR, expressed in both TRAIL-sensitive and TRAIL-resistant triple-negative breast cancer cell lines, using a small molecule tyrosine kinase inhibitor (AG1478), enhanced TRAIL-induced apoptosis in TRAIL-sensitive cell lines but did not convert resistant cells into TRAIL-sensitive cells. Together, these findings suggest that a subset of triple-negative breast cancer, those with mesenchymal features, may be the most likely to benefit from TRAIL targeted therapy. These findings could form the basis to select breast cancer patients for clinical trials of TRAIL-R2 ligands.

cbl-3: a new mammalian cbl family protein.

We have cloned a new human gene, cbl-3, which encodes a protein with marked homology to the cbl family of proteins. The predicted protein encoded by this gene retains the conserved phosphotyrosine binding domain (PTB) in the N-terminal and the zinc finger but is significantly shorter (MW 52.5 kDa) than the other mammalian cbl proteins. The protein lacks the extensive proline rich domain and leucine zipper seen in c-cbl and cbl-b and structurally most resembles the C. elegans and Drosophila cbl proteins. The gene is ubiquitously expressed with highest expression in the aerodigestive tract, prostate, adrenal gland, and salivary gland. The protein is phosphorylated and recruited to the EGFR upon EGF stimulation and inhibits EGF stimulated MAP kinase activation. In comparison to the other mammalian cbl proteins (e.g. cbl-b), cbl-3 interacts with a restricted range of proteins containing Src Homology 3 regions. An alternatively spliced form of the cbl-3 protein was also identified which deletes a critical region of the PTB domain and which does not interact with the EGFR nor inhibit EGF stimulated MAP kinase activation. These data demonstrate that cbl-3, a novel mammalian cbl protein, is a regulator of EGFR mediated signal transduction.

cbl -b inhibits epidermal growth factor receptor signaling

The role of cbl-b in signaling by the epidermal growth factor receptor (EGFR) was studied and compared with c-cbl. We demonstrate in vivo, that cbl-b, like c-cbl, is phosphorylated and recruited to the EGFR upon EGF stimulation and both cbl proteins can bind to the Grb2 adaptor protein. To investigate the functional role of cbl proteins in EGFR signaling, we transfected cbl-b or c-cbl into 32D cells overexpressing the EGFR (32D/EGFR). This cell line is absolutely dependent on exogenous IL-3 or EGF for sustained growth. 32D/EGFR cells overexpressing cbl-b showed markedly inhibited growth in EGF compared to c-cbl transfectants and vector controls. This growth inhibition by cbl-b was the result of a dramatic increase in the number of cells undergoing apoptosis. Consistent with this finding, cbl-b overexpression markedly decreased the amplitude and duration of AKT activation upon EGF stimulation compared to either vector controls or c-cbl overexpressing cells. In addition, the duration of EGF mediated MAP kinase and Jun kinase activation in cells overexpressing cbl-b is shortened. These data demonstrate that cbl-b inhibits EGF-induced cell growth and that cbl-b and c-cbl have distinct roles in EGF mediated signaling.

Translation and translocation of defined RNA messengers

Abstract A purified system for protein synthesis, derived from Esherichia coli , makes use of small, synthetic mRNAs initiated by the fMet ‡ codon, AUG, followed by a sequence of 3, 6 or 9 uridylic acid residues. These di-, tri- and tetra-codons direct the binding of fMet- and Phe-tRNA to ribosomes and the synthesis of the corresponding fMet-initiated di-, tri- and tetrapeptides. This system, directing the synthesis of unique and conveniently detected oligopeptide products, has permitted us to correlate the soluble elements required for protein synthesis with specific steps in the translation of initial and succeeding codons. Complete translation of these small mRNAs has certain of the stringent requirements necessary for the accurate cell-free translation of naturally occurring RNA messengers. Thus, initiation factors, fMet-tRNA and GTP must be provided. After recognition of the first codon and formation of the initial complex, one of two transfer factors, in the presence of GTP, catalyzes a binding reaction in which the second (first internal) codon is recognized. This permits formation of the dipeptide, fMet-Phe, but does not permit translation of succeeding codons. A second transfer factor, probably an enzyme, participates in a translocation reaction in which the third codon is made available for translation, apparently displacing the second codon at the recognition site on the ribosome. In addition, the complex formed between peptidyl-tRNA, mRNA and ribosome is stabilized, possibly by translocation of the peptidyl-tRNA from a site of lesser affinity to one of greater affinity on the ribosome. The role of GTP in the translocation reaction will be certain only when it has been uncoupled from its participation in the binding reaction. Once requirements for translation of the third codon have been met no further additions are necessary for elongation of the peptide chain.

Inhibition of NF-κB Activity Enhances TRAIL Mediated Apoptosis in Breast Cancer Cell Lines

Most breast cancer cell lines are resistant to TNF-related apoptosis inducing ligand (TRAIL) induced apoptosis. In sensitive breast cancer cell lines TRAIL rapidly induces the cleavage and activation of caspases leading to the subsequent cleavage of downstream caspase substrates. In contrast, there is no caspase activation in the resistant cell lines. The transcription factor NF-κB can inhibit apoptosis induced by a variety of stimuli including activation of death receptors. We investigated whether NF-κB contributes to the resistance of breast cancer cells to TRAIL induced apoptosis. All of the resistant breast cancer cell lines expressed NF-κB and had detectable NF-κB activity in nuclear extracts prior to treatment with TRAIL. Upon TRAIL treatment, a significant increase in NF-κB activity was seen in most of the cell lines. To directly test if NF-κB activity contributes to the resistance of these cell lines to TRAIL, we transiently transfected the resistant cell lines with an inhibitor of NF-κB (IκBΔN) and measured TRAIL induced apoptosis in control and transfected cells. All of the resistant cell lines tested showed an increase in TRAIL induced apoptosis when transfected with the IκBΔN. These results demonstrate that TRAIL resistant breast cancer cells fail to rapidly activate the apoptotic machinery but they do activate NF-κB. Inhibition of NF-κB activity increases the sensitivity to TRAIL mediated apoptosis in resistant cells. These results suggest that agents which inhibit NF-κB should increase the clinical efficacy of TRAIL in breast cancer cells.

Cbl and human myeloid neoplasms: the Cbl oncogene comes of age

Cbl was originally discovered in 1989 as the cellular homolog of the v-Cbl oncogene, the transforming gene of the Cas NS-1 murine retrovirus that causes myeloid leukemia and lymphomas in mice. Cbl is a member of a family of RING finger ubiquitin ligases that negatively regulate signaling by tyrosine kinases and that function as adaptor proteins to regulate signaling positively. Until the past 2 years, there was little evidence that Cbl proteins were involved in human malignancies. Recent publications have shown homozygous mutations in Cbl in human myeloid neoplasms. Although in vitro and animal transformation models suggested that mutant forms of Cbl acted as an oncogene, the cellular role suggested that the protein could serve as a tumor suppressor gene. The recent data begin to reconcile this paradox as the loss of ubiquitin ligase function (the tumor suppressor function) is coupled to the maintenance of the positive signaling function (the oncogene function). These data also provide insight into potential therapeutic approaches to myeloid disorders harboring Cbl mutations.

Hereditary and acquired p53 gene mutations in childhood acute lymphoblastic leukemia.

The p53 gene was examined in primary lymphoblasts of 25 pediatric patients with acute lymphoblastic leukemia by the RNase protection assay and by single strand conformation polymorphism analysis in 23 of 25 cases. p53 mutations were found to occur, but at a low frequency (4 of 25). While all four mutations were identified by single strand conformation polymorphism, the comparative sensitivity of RNase protection was 50% (2 of 4). Heterozygosity was retained at mutated codons in 3 of 4 cases. One pedigree was consistent with the Li-Fraumeni syndrome, and bone marrow from both diagnosis and remission indicated a germline G to T transversion at codon 272 (valine to leucine). Although members of another family were affected with leukemia, a 2-bp deletion in exon 6 was nonhereditary. The other two nonhereditary p53 mutations included a T to G transversion at codon 270 (phenylalanine to cysteine) and a G to C transversion at codon 248 (arginine to proline). These data support the role of both hereditary and acquired p53 mutations in the pathogenesis and/or progression of some cases of childhood acute lymphoblastic leukemia.

Cbl-b interacts with ubiquitinated proteins ; differential functions of the UBA domains of c-Cbl and Cbl-b

Cbl proteins are ubiquitin protein ligases, which ubiquitinate activated tyrosine kinases and target them for degradation. Both c-Cbl and Cbl-b have an ubiquitin associated (UBA) domain at their C-terminal end. We observed that high molecular weight ubiquitinated proteins constitutively coimmunoprecipitated with transfected and endogenous Cbl-b, but not c-Cbl. The binding site for these ubiquitinated proteins was mapped to the UBA domain of Cbl-b (UBAb). GST-fusion proteins containing the UBAb interacted with ubiquitinated proteins and polyubiquitin chains in vitro, whereas those containing the UBA domain of c-Cbl (UBAc) did not. The UBAb had a much greater affinity for polyubiquitin chains than for monoubiquitin. Analysis of the UBAb and UBAc demonstrate that the affinity for ubiquitin is determined by multiple amino-acid differences between the two domains. Overexpression of the UBAb, but not overexpression of the UBAc, inhibited a variety of ubiquitin-mediated processes such as degradation of ubiquitinated proteins (i.e. EGFR, Mdm-2, and Siah-1). This in vivo result is consistent with the differences in ubiquitin binding observed in vitro between the UBAb and UBAc. This difference in ubiquitin-binding may reflect distinct regulatory functions of c-Cbl and Cbl-b.

Cbl-3-deficient mice exhibit normal epithelial development

ABSTRACT Cbl family proteins are evolutionarily conserved ubiquitin ligases that negatively regulate signaling from tyrosine kinase-coupled receptors. The mammalian cbl family consists of c-Cbl, Cbl-b, and the recently cloned Cbl-3 (also known as Cbl-c). In this study, we describe the detailed expression pattern of murine Cbl-3 and report the generation and characterization of Cbl-3-deficient mice. Cbl-3 exhibits an expression pattern distinct from those of c-Cbl and Cbl-b, with high levels of Cbl-3 expression in epithelial cells of the gastrointestinal tract and epidermis, as well as the respiratory, urinary, and reproductive systems. Cbl-3 expression was not detected in nonepithelial cells, but within epithelial tissues, the levels of Cbl-3 expression varied from undetectable in the alveoli of the lungs to very strong in the cecum and colon. Despite this restricted expression pattern, Cbl-3-deficient mice were viable, healthy, and fertile and displayed no histological abnormalities up to 18 months of age. Proliferation of epithelial cells in the epidermises and gastrointestinal tracts was unaffected by the loss of Cbl-3. Moreover, Cbl-3 was not required for attenuation of epidermal growth factor-stimulated Erk activation in primary keratinocytes. Thus, Cbl-3 is dispensable for normal epithelial development and function.