Richard Bertrand

DNA-damage response network at the crossroads of cell-cycle checkpoints, cellular senescence and apoptosis

Tissue homeostasis requires a carefully-orchestrated balance between cell proliferation, cellular senescence and cell death. Cells proliferate through a cell cycle that is tightly regulated by cyclin-dependent kinase activities. Cellular senescence is a safeguard program limiting the proliferative competence of cells in living organisms. Apoptosis eliminates unwanted cells by the coordinated activity of gene products that regulate and effect cell death. The intimate link between the cell cycle, cellular senescence, apoptosis regulation, cancer development and tumor responses to cancer treatment has become eminently apparent. Extensive research on tumor suppressor genes, oncogenes, the cell cycle and apoptosis regulatory genes has revealed how the DNA damage-sensing and-signaling pathways, referred to as the DNA-damage response network, are tied to cell proliferation, cell-cycle arrest, cellular senescence and apoptosis. DNA-damage responses are complex, involving “sensor” proteins that sense the damage, and transmit signals to “transducer” proteins, which, in turn, convey the signals to numerous “effector” proteins implicated in specific cellular pathways, including DNA repair mechanisms, cell-cycle checkpoints, cellular senescence and apoptosis. The Bcl-2 family of proteins stands among the most crucial regulators of apoptosis and performs vital functions in deciding whether a cell will live or die after cancer chemotherapy and irradiation. In addition, several studies have now revealed that members of the Bcl-2 family also interface with the cell cycle, DNA repair/recombination and cellular senescence, effects that are generally distinct from their function in apoptosis. In this review, we report progress in understanding the molecular networks that regulate cell-cycle checkpoints, cellular senescence and apoptosis after DNA damage, and discuss the influence of some Bcl-2 family members on cell-cycle checkpoint regulation.

Apoptosis Induced by DNA Topoisomerase I and II Inhibitors in Human Leukemic HL-60 Cells

The induction of apoptosis following topoisomerase inhibitors proceeds in at least three distinct steps: (1) induction of cleavable complexes (potentially lethal damage), (2) topoisomerase-induced DNA damage, and (3) a presently unknown sequence of events that must either lead to cell cycle arrest (G2-block, differentiation) or apoptosis. DNA degradation provides a convenient way to quantify apoptosis in HL-60 cells. Extensive apoptosis can be induced rapidly in undifferentiated HL-60 cells without prevention by cycloheximide or actinomycin D. Therefore, HL-60 cells appear to express constitutively the apoptotic machinery that may be kept under control of a yet unknown repressor. The absence of the tumor suppressor p53 and the presence of bcl-2 are in contrast with the sensitivity of these cells to apoptosis. Agents that modify chromatin structure (zinc, poly[ADPribose] inhibitors, spermine) can block DNA fragmentation without affecting cell survival. By contrast macrophage-like differentiation by phorbol esters suppresses apoptosis without affecting topoisomerase-induced DNA damage. Better understanding of the apoptotic regulation in the widely used and characterized HL-60 cell line should allow the identification of new mechanisms and parameters of cellular sensitivity and resistance to the cytotoxic activity of anticancer agents.

Bax-alpha promotes apoptosis induced by cancer chemotherapy and accelerates the activation of caspase 3-like cysteine proteases in p53 double mutant B lymphoma Namalwa cells.

Stable transfected human p53 (mt/mt) B lymphoma Namalwa variant lines showing differential expression of the Bax-α protein were derived under hygromycin selection. Overexpression of Bax-α in these variant cells accelerates cell death induced by short or continuous treatments with various concentrations of camptothecin, etoposide, vinblastine and shows no accelerating cell death activity in cis-platinum and paclitaxel-treated cells. Activation of apoptosis and oligonucleosome-sized DNA fragmentation was observed in the variant lines with more pronounced effect in cells containing high level of Bax-α protein. These results suggest that increased cell death mediated by anticancer drugs correlates with Bax-α level of expression and that Bax-α sensitizes Namalwa cells treated at low drug concentrations. The extent of DNA synthesis inhibition following DNA topoisomerase inhibitor treatments was similar in control and all transfected Namalwa cells suggesting that Bax-α acts downstream of DNA topoisomerase-mediated DNA strand breaks. To define further the relation between Bax-α expression and apoptosis activation, kinetics of caspase activation was measured in drug-treated cells. Caspase activities were measured using specific fluorogenic peptide derivatives DABCYL-YVADAPV-EDANS and Ac-DEVD-AMC, substrates of the caspase 1-like and caspase 3-like families, respectively. In control and Bax-α transfected Namalwa cells no increase in caspase 1-like activity was detected following camptothecin and etoposide treatments. In contrast, a significant difference in Ac-DEVD-AMC hydrolysis activity was observed in Bax-α transfected Namalwa cells compared to that of control Namalwa cells after camptothecin and etoposide treatment. Increased caspase 3-like activity correlated also with poly(ADPribosyl) polymerase cleavage. Taken together, these results suggest that Bax-α sensitize B lymphoma cells to series of anticancer drugs and accelerates the activation of apoptotic protease cascade.

Activation of multidomain and BH3-only pro-apoptotic Bcl-2 family members in p53-defective cells

In the p53-deficient human B lymphoma Namalwa cell line that quickly undergoes apoptosis after DNA topoisomerase I inhibitor (camptothecin, CPT) treatment, we observed rapid and slight induction of the pro-apoptotic BH3-only Bik, Bim-EL, Bim-L and Bim-S proteins. In contrast, the expression levels of Bad and multidomain Bax-α and Bak remained mostly unchanged after CPT treatment. However, multiple pro-apoptotic proteins, including Bax-α, Bak, Bik, Bim-EL and Bim-L, translocated rapidly to the mitochondria after CPT treatment. Gel filtration chromatography experiments demonstrated that somes of the pro-apoptotic proteins assemble themselves into high molecular weight protein complexes. The protein composition of these oligomers was further analyzed by co-immunoprecipitation experiments performed on highly purified mitochondrial fractions, which revealed the formation of Bax/Bak, Bax/VDAC1, Bak/VDAC1, Bim/VDAC1 and Bim/Bcl-2 complexes after DNA damage induction. Thus, it appeared that induction, mitochondrial translocation and assembly in multimeric protein complexes of several pro-apoptotic members of the Bcl-2 family correlated with the rapid activation of apoptosis in a p53-independent pathway after CPT-mediated DNA strand breaks.

Proteomic analysis of enriched lysosomes at early phase of camptothecin-induced apoptosis in human U-937 cells.

A lysosomal pathway, characterized by partial rupture or labilization of lysosomal membranes and cathepsin activation, is evoked during camptothecin-induced apoptosis in human cancer cells, including human histiocytic lymphoma U-937 cells. These lysosomal events begin rapidly and simultaneously with mitochondrial permeabilization and caspase activation within 3 h after drug treatment. In this study, comparative and quantitative proteome analyses were performed to identify early changes in lysosomal protein expression/localization from U-937 cells undergoing apoptosis. In 2 independent experiments, among a total of more than 538 proteins putatively identified and quantitated by iTRAQ isobaric labeling and LC-ESI-MS/MS, 18 proteins were found to be upregulated and 9 downregulated in lysosomes purified from early apoptotic compared to control cells. Protein expression was validated by Western blotting on enriched lysosome fractions, and protein localization confirmed by fluorescence confocal microscopy of representative protein candidates, whose functions are associated with lysosomal membrane fluidity and dynamics. These include sterol-4-alpha-carboxylate 3-dehydrogenase (NSDHL), prosaposin (PSAP) and protein kinase C delta (PKC-delta). This comparative proteome analysis provides the basis for novel hypothesis and rationale functional experimentation, where the 3 validated candidate proteins are associated with lysosomal membrane fluidity and dynamics, particularly cholesterol, sphingolipid and glycosphingolipid metabolism.

Cloning and characterization of the human 5,10-methenyltetrahydrofolate synthetase-encoding cDNA

Methenyltetrahydrofolate synthetase (MTHFS) catalyses the obligatory initial metabolic step in the intracellular conversion of 5-formyltetrahydrofolate to other reduced folates. We have isolated and sequenced a human MTHFS cDNA which is 872-bp long and codes for a 203-amino-acid protein of 23,229 Da. Escherichia coli BL21(DE3), transfected with pET11c plasmids containing an open reading frame encoding MTHFS, showed a 100-fold increase in MTHFS activity in bacterial extracts after IPTG induction. Northern blot studies of human tissues determined that the MTHFS mRNA was expressed preferentially in the liver and Southern blot analysis of human genomic DNA suggested the presence of a single-copy gene.

Procaspase-2S inhibits procaspase-3 processing and activation, preventing ROCK-1-mediated apoptotic blebbing and body formation in human B lymphoma Namalwa cells

Procaspase-2S has been reported to selectively prevent membrane blebbing and apoptotic body formation in human monocytic-like leukemic U937 cells after etoposide (VP-16) treatment (Droin et al., Oncogene 20. 260–269, 2001). Here, we show that procaspase-2S overexpressed in human B lymphoma Namalwa cells inhibits procaspase-3 processing and activation, preventing cleavage and activation of Rho GTPase-associated ROCK-1 kinase. Failure of ROCK-1 activation in Namalwa cells correlates with a sustained delay in the appearance of membrane blebbing and apoptotic body formation after VP-16 treatment. Reciprocal coimmunoprecipitation experiments indicate that procaspase-2S binds to procaspase-3, but not procaspase-2L and -9 in untreated and VP-16-treated Namalwa cells. These data suggest that procaspase-2S-mediated anti-apoptotic effects are associated with inhibition of the processing and activation of procaspase-3 in VP-16-treated cells.

Bcl-xL phosphorylation at Ser49 by polo kinase 3 during cell cycle progression and checkpoints

Functional analysis of a Bcl-xL phosphorylation mutant series has revealed that cells expressing Bcl-xL(Ser49Ala) mutant are less stable at G2 checkpoint after DNA damage and enter cytokinesis more slowly after microtubule poisoning, than cells expressing wild-type Bcl-xL. These effects of Bcl-xL(Ser49Ala) mutant seem to be separable from Bcl-xL function in apoptosis. Bcl-xL(Ser49) phosphorylation is cell cycle-dependent. In synchronized cells, phospho-Bcl-xL(Ser49) appears during the S phase and G2, whereas it disappears rapidly in early mitosis during prometaphase, metaphase and early anaphase, and re-appears during telophase and cytokinesis. During DNA damage-induced G2 arrest, an important pool of phospho-Bcl-xL(Ser49) accumulates in centrosomes which act as essential decision centers for progression from G2 to mitosis. During telophase/cytokinesis, phospho-Bcl-xL(Ser49) is found with dynein motor protein. In a series of in vitro kinase assays, specific small interfering RNA and pharmacological inhibition experiments, polo kinase 3 (PLK3) was implicated in Bcl-xL(Ser49) phosphorylation. These data indicate that, during G2 checkpoint, phospho-Bcl-xL(Ser49) is another downstream target of PLK3, acting to stabilize G2 arrest. Bcl-xL phosphorylation at Ser49 also correlates with essential PLK3 activity and function, enabling cytokinesis and mitotic exit.

Identification and characterization of human mitochondrial methenyltetrahydrofolate synthetase activity

We present evidence for the presence of the folate metabolism enzyme methenyltetrahydrofolate synthetase (MTHFS) in mitochondria. MTHFS activity was identified in the matrix of mitochondria purified from human liver biopsies. Mitochondrial and cytoplasmic MTHFS specific activities are similar, 85% of the total cellular MTHFS activity is in the cytoplasm and both native enzymes have similar molecular weights (approximately 25 kDa). Studies using purified mitochondrial MTHFS from CA46 human Burkitt lymphoma cells reveal that mitochondrial MTHFS behaves kinetically like the cytoplasmic enzyme with Km values of 4.7, 0.8 and 22 microM respectively for (6R,S)-5-formyltetrahydrofolate monoglutamate, (6S)-5-formyltetrahydrofolate pentaglutamate and ATP. This finding adds to previous observations that various folate-dependent enzymes reside in the mitochondria of eucaryotic cells. Intracellular tetrahydrofolate metabolism is highly compartmentalized and mitochondrial MTHFS activity is necessary for the entry of mitochondrial 5-formyltetrahydrofolate into the mitochondrial folate pool.

Biochemical and Molecular Studies of Human Methenyltetrahydrofolate Synthetase

5‐FormylH4folate is administered clinically under the name Leucovorin™ in association with the antineoplastic agent 5‐fluorouracil (5‐FU) to enhance the cytotoxic effects of 5‐FU. The combination has been shown to be superior to 5‐FU alone in the treatment of patients with metastatic colorectal carcinoma. Methenyltetrahydrofolate synthetase (MTHFS) catalyzes the transformation of 5‐formyltetrahydrofolate to methenylH4folate, which is the obligatory initial metabolic step prior to the intracellular conversion of 5‐formylH4folate to other reduced folates and the increase in intracellular folate pools required for 5‐FU potentiation. In the following paper, we will summarize results of biochemical and molecular studies of human MTHFS.