Re-evaluating the role of FOXOs in cancer.

FOXO transcription factors are negatively regulated by the PI3K-PKB/AKT signaling pathway and have been mainly considered to be tumor suppressors due to their inhibitory effect on cancer cell growth and survival. However, FOXOs can also support tumor development and progression by maintaining cellular homeostasis, facilitating metastasis and inducing therapy resistance. In agreement with these opposing views on the role of FOXOs in cancer, studies using FOXO levels or activity as prognostic markers for cancer patient disease progression and survival came to contradicting results. While it is clear that FOXOs are involved in various aspects of cancer, it is debatable whether FOXOs function as tumor suppressors or supporters, or may be both depending on the context. In this review, we describe the role of FOXOs in signaling pathways and processes relevant to cancer and evaluate recent advances in understanding the role of FOXOs in cancer. Based on recent insights it becomes clear that FOXOs may not be classical tumor suppressors and that targeting FOXO activity might hold promise in cancer therapy.

Restraining FOXO3-dependent transcriptional BMF activation underpins tumour growth and metastasis of E-cadherin-negative breast cancer.

Loss of cellular adhesion leads to the progression of breast cancer through acquisition of anchorage independence, also known as resistance to anoikis. Although inactivation of E-cadherin is essential for acquisition of anoikis resistance, it has remained unclear how metastatic breast cancer cells counterbalance the induction of apoptosis without E-cadherin-dependent cellular adhesion. We report here that E-cadherin inactivation in breast cancer cells induces PI3K/AKT-dependent FOXO3 inhibition and identify FOXO3 as a novel and direct transcriptional activator of the pro-apoptotic protein BMF. As a result, E-cadherin-negative breast fail to upregulate BMF upon transfer to anchorage independence, leading to anoikis resistance. Conversely, expression of BMF in E-cadherin-negative metastatic breast cancer cells is sufficient to inhibit tumour growth and dissemination in mice. In conclusion, we have identified repression of BMF as a major cue that underpins anoikis resistance and tumour dissemination in E-cadherin-deficient metastatic breast cancer.

Oncogene-dependent tumor suppression: using the dark side of the force for cancer therapy.

Cancers arise by an evolutionary process that involves the protracted acquisition by somatic cells of suites of interlocking mutations that uncouple proliferation, survival, migration, and damage responses from the mechanisms (selective pressures) that normally restrain or restrict them in time and space. The relative rareness of cancer cells within the soma, in the face of huge numbers of available cell targets, substantial rates of mutation, and an abundance of proto-oncogenes and tumor suppressor gene targets, indicates that the evolutionary space available to incipient tumor cells is highly restricted. The principal way in which this is achieved is through intrinsic tumor suppression pathways-innate growth arrest and apoptotic programs that fulfill an essentially analogous functional role to checkpoints in the cell cycle machinery by antagonizing the tumorigenic potential of oncogenic mutations. Using switchable transgenic and knockin mouse models, it is possible to identify these various tumor suppressor programs and establish where, when, how, and why they act to forestall neoplasia in each tissue type and, consequently, how and why their failure leads to cancer.

The peroxisome in oxidative stress.

Peroxisomes are one of the main sites in the cell where oxygen free radicals are both generated and scavenged. The balance between these two processes is believed to be of great importance for proper functioning of cells and has been implicated in aging and carcinogenesis. We will give an overview of the peroxisomal processes involved in the oxygen radical homeostasis and its implications for the cell.

Targeted fluorescent probes in peroxisome function.

Fluorescent peptides form a new generation of analytical tools for visualizing intracellular processes and molecular interactions at the level of single cells. The peptide-based reporters combine the sensitivity of fluorescence detection with the information specificity of amino acid sequences. Recently we have succeeded in targeting a fluorescent heptapeptide (acetyl-CKGGAKL) carrying a peroxisomal targeting signal (PTS1) to peroxisomes in intact cells. The fluorophores conjugated to the PTS1-peptide were fluorescein, BODIPY and the pH-sensitive SNAFL-2. When added to cells, these fluorescent peptides were internalized at 37 degrees C and typically visible in the cell after 15 min or less. Cells lacking an active peroxisomal protein import system, as in the case of Zellweger syndrome, were stained diffusely throughout the cell. Uptake of the peptide probes was not inhibited at 4 degrees C or when the cells were depleted of ATP. Under these conditions translocation to peroxisomes was blocked. This indicates that the uptake by cells is diffusion-driven and not an active process. Using the SNAFL-2-PTS1 peptide, we established by ratio-imaging that peroxisomes of human fibroblasts have an internal pH of 8.2. The concurrent pH gradient over the peroxisomal membrane was dissipated when an ionophore (CCCP) was added. In fibroblasts of chondrodysplasia punctata patients with defects in the peroxisomal import of proteins carrying a PTS2 sequence, import of the PTS1-peptide probe into peroxisomes appeared normal, but these peroxisomes have a pH of 6.8 equal to that of the cytosol. Coupling different fluorophores to the PTS1-peptide offers the possibility of determining in time and space as to how peroxisomes function in living cells.

Peptide-based targeting of fluorophores to organelles in living cells.

Peptides carrying organelle-specific import or retention sequences can target the fluorophore BODIPY(581/591) to the nucleus, peroxisomes, endoplasmic reticulum (ER), or the trans-Golgi network (TGN). The peroxisomal peptide contains the PTS1 sequence AKL. For targeting to the ER or TGN, the peptides carry the retention sequences KDEL and SDYQRL, respectively. A peptide carrying the nuclear leader sequence of the simian virus SV40 large tumor antigen, KKKRK, was used to direct the fluorophore to the nucleus. The fluorescent peptides for peroxisomes, ER, and the TGN spontaneously incorporate into living fibroblasts at 37 degrees C and accumulate in their target organelles within minutes. The uptake is still significant at 4 degrees C, indicating that endocytosis is not required for internalization. The highly charged nuclear peptide (net charge +4) does not spontaneously internalize. However, by transient permeabilization of the plasma membrane, this fluorescent peptide was found to rapidly accumulate in the nucleus. These fluorescent peptides open new opportunities to follow various aspects of specific organelles such as their morphology, biogenesis, dynamics, degradation, and their internal parameters (pH, redox).

Peptide-based targeting of fluorophores to peroxisomes in living cells.

Peptides carrying different fluorophores can be designed to incorporate spontaneously into living cells when added to the medium. By incorporating the peroxisome-targeting sequence PTS1, the peptide is recognized by the protein-import machinery of peroxisomes and, as a result, can accumulate in these organelles. Depending on the cell type, an inhibitor of the multidrug-resistance protein might be required to ensure strong accumulation. In this update, we discuss the potential of these peptide-linked fluorophores in solving issues related to organelle function and dynamics.

Immunological analyses of alkyl-dihydroxyacetone-phosphate synthase in human peroxisomal disorders.

Alkyl-dihydroxyacetonephosphate synthase (alkyl-DHAP synthase) is a peroxisomal enzyme involved in the biosynthesis of ether phospholipids. To localize the enzyme in human peroxisomal disorders, indirect immunofluorescence and immunoblot analysis was performed. In Zellweger syndrome and rhizomelic chondrodysplasia punctata fibroblast cell lines, alkyl-DHAP synthase protein levels on immunoblots were strongly decreased and residual immunofluorescence was diffusely localized throughout the cytoplasm. In a particular neonatal adrenoleukodystrophy cell line, characterized by the absence of a functional peroxisomal targeting signal 1 receptor, the precursor form of the enzyme was detected in Western blots at levels comparable to that of the mature enzyme in control fibroblasts. Similarly, fibroblasts from patients with a single deficiency in the activity of either alkyl-DHAP synthase or DHAP-acyltransferase showed normal levels of the mature alkyl-DHAP synthase protein on immunoblots. Immunofluorescence experiments revealed a peroxisomal localization of both the precursor and the mature form of the enzyme. Collectively, these results visualize the peroxisomal localization of alkyl-DHAP synthase, indicate that the enzyme is unstable outside its target organelle and explain that normal enzyme protein levels found in some peroxisomal disorders result from protection against cytoplasmic degradation through import into peroxisomes. Additionally, alkyl-DHAP synthase could be detected in rat mesangial cells and murine NIH-3R3 fibroblasts by immunofluorescence as well as immunoblot analysis. Immunoelectron microscopy showed that the enzyme is predominantly located on the lumenal side of the peroxisomal membrane in rat and guinea pig liver.

High-affinity binding of very-long-chain fatty acyl-CoA esters to the peroxisomal non-specific lipid-transfer protein (sterol carrier protein-2).

Binding of fluorescent fatty acids to bovine liver non-specific lipid-transfer protein (nsL-TP) was assessed by measuring fluorescence resonance energy transfer (FRET) between the single tryptophan residue of nsL-TP and the fluorophore. Upon addition of pyrene dodecanoic acid (Pyr-C12) and cis-parinaric acid to nsL-TP, FRET was observed indicating that these fatty acids were accommodated in the lipid binding site closely positioned to the tryptophan residue. Substantial binding was observed only when these fatty acids were presented in the monomeric form complexed to beta-cyclodextrin. As shown by time-resolved fluorescence measurements, translocation of Pyr-C12 from the Pyr-C12-beta-cyclodextrin complex to nsL-TP changed dramatically the direct molecular environment of the pyrene moiety: i.e. the fluorescence lifetime of the directly excited pyrene increased at least by 25% and a distinct rotational correlation time of 7 ns was observed. In order to evaluate the affinity of nsL-TP for intermediates of the beta-oxidation pathway, a binding assay was developed based on the ability of fatty acyl derivatives to displace Pyr-C12 from the lipid binding site as reflected by the reduction of FRET. Hexadecanoyl-CoA and 2-hexadecenoyl-CoA were found to bind readily to nsL-TP, whereas 3-hydroxyhexadecanoyl-CoA and 3-ketohexadecanoyl-CoA bound poorly. The highest affinities were observed for the very-long-chain fatty acyl-CoA esters (24:0-CoA, 26:0-CoA) and their enoyl derivatives (24:1-CoA, 26:1-CoA). Binding of non-esterified hexadecanoic acid and tetracosanoic acid (24:0) was negligible.