Orazio Cantoni

TNF-α downregulates eNOS expression and mitochondrial biogenesis in fat and muscle of obese rodents

Obesity is associated with chronic low-grade inflammation. Thus, at metabolically relevant sites, including adipose tissue and muscle, there is abnormal production of proinflammatory cytokines such as TNF-alpha. Here we demonstrate that eNOS expression was reduced, with a concomitant reduction of mitochondrial biogenesis and function, in white and brown adipose tissue and in the soleus muscle of 3 different animal models of obesity. The genetic deletion of TNF receptor 1 in obese mice restored eNOS expression and mitochondrial biogenesis in fat and muscle; this was associated with less body weight gain than in obese wild-type controls. Furthermore, TNF-alpha downregulated eNOS expression and mitochondrial biogenesis in cultured white and brown adipocytes and muscle satellite cells of mice. The NO donors DETA-NO and SNAP prevented the reduction of mitochondrial biogenesis observed with TNF-alpha. Our findings demonstrate that TNF-alpha impairs mitochondrial biogenesis and function in different tissues of obese rodents by downregulating eNOS expression and suggest a novel pathophysiological process that sustains obesity.

Apoptosis and necrosis following exposure of U937 cells to increasing concentrations of hydrogen peroxide: the effect of the poly(ADP-ribose)polymerase inhibitor 3-aminobenzamide.

A 3-hr exposure of U937 cells to hydrogen peroxide (H2O2) followed by a 6-hr posttreatment incubation in fresh culture medium promotes apoptosis or necrosis, depending on the oxidant concentration. Addition of 3-aminobenzamide (3AB) during the recovery phase prevented necrosis and caused apoptosis. 3AB did not, however, affect the apoptotic response of cells treated with apogenic concentrations of H2O2. Cells exposed for 3 hr to 1.5 mM H2O2, while showing some signs of suffering, maintained a normal nuclear organization and good organelle morphology. At the biochemical level, the oxidant promoted the formation of Mb-sized DNA fragments and rapidly depleted both the adenine nucleotide and non-protein sulphydryl pools, which did not recover during posttreatment incubation in the absence or presence of 3AB. These results allow a novel interpretation of the concentration-dependent switch from apoptosis to necrosis. We propose that H2O2 activates the apoptotic response at the early times of peroxide exposure and that this process can be completed, or inhibited, during the posttreatment incubation phase. Inhibition of apoptosis leads to necrosis and can be prevented by 3AB via a mechanism independent of inhibition of poly(ADP-ribose)polymerase. As a corollary, the necrotic response promoted by high concentrations of H2O2 in U937 cells appears to be the result of specific inhibition of the late steps of apoptosis.

Prevention of necrosis and activation of apoptosis in oxidatively injured human myeloid leukemia U937 cells

A 3 h exposure to 1 mM H2O2 followed by 6 h post‐challenge growth in peroxide‐free medium induces necrosis in U937 cells. Addition of the poly(ADP‐ribose)polymerase inhibitor 3‐aminobenzamide during recovery prevents necrosis and triggers apoptosis, as shown by the appearance of apoptotic bodies, extensive blebbing and formation of multimeric DNA fragments as well as 50 kb double stranded DNA fragments. Thus, the same initial damage can be a triggering event for both apoptotic and necrotic cell death. Furthermore, necrosis does not appear to be a passive response to overwhelming damage.

Induction and repair of DNA single-strand breaks in EM9 mutant CHO cells treated with hydrogen peroxide

In this study we investigated the induction and rejoining of DNA single-strand breaks (SSBs) produced by H2O2 in the repair-deficient EM9 mutant Chinese hamster ovary (CHO) cell line. The effect of the poly(ADP-ribose)-transferase inhibitor 3-aminobenzamide (3-ABA) on SSB-rejoining and on cell killing was also evaluated. Results were compared with those obtained previously with the parent cell line (AA8). Cells were treated with H2O2 on ice for 1 h, after which they were either harvested or allowed to repair their damage at 37 degrees C either in the presence or absence of 3-ABA (5 mM). The cells were then assayed either for survival using a colony-forming assay or for their level of DNA SSBs using alkaline elution. EM9 cells were somewhat more sensitive than AA8 cells to the cytotoxic effects of H2O2. However, because the repair mutant showed slightly lower levels of DNA SSBs than did its parental cell line, this sensitivity could not be explained on the basis of alterations in initial damage. The rejoining of the H2O2-induced DNA SSBs followed exponential kinetics in both cell lines; however, EM9 cells rejoined these breaks at a slower rate (t1/2 of 10 min) than did AA8 cells (t1/2 of 5 min). The increased sensitivity of the EM9 cells therefore appears to correlate with a reduced ability to remove these lesions from their DNA. As previously demonstrated for the AA8 cells, 3-ABA treatment resulted in both a retardation of the removal of H2O2-induced DNA SSBs and potentiation of cytotoxicity in the EM9 cells. However, the degree of these effects were similar for both AA8 and EM9 cells. These data provide further evidence that the cytotoxic effects of low concentrations of H2O2 are mediated by damage to DNA, and suggest that the rate at which DNA SSBs are rejoined is important for cell survival.

Osmotically driven radial diffusion of single-stranded DNA fragments on an agarose bed as a convenient measure of DNA strand scission.

The present study describes the development and characterization of a novel technique, the alkaline-halo assay, for the assessment of DNA single strand breakage in mammalian cells. This technique allows the measurement of DNA lesions at the single cell level and presents the additional advantages of being rapid, sensitive, virtually costless and environmentally friendly, because it does not require the use of isotopes. The alkaline halo assay involves a series of sequential steps in which the cells are first treated, then embedded in melted agarose and spread onto microscope slides that are incubated for 2 min at ice-bath temperature to allow complete geling. The slides are then incubated for 20 min in a high salt alkaline lysis solution, for an additional 15 min in a hypotonic alkaline solution and, finally, for 10 min in ethidium bromide. Under these conditions, single-stranded DNA fragments spread radially from the nuclear cage and generate a fluorescent image that resembles a halo concentric to the nucleus remnants. The area of the halos increased at increasing levels of DNA fragmentation and this process was associated with a progressive reduction of areas of the nuclear remnants. These events were conveniently monitored with a fluorescence microscope and quantified by image processing analysis. The sensitivity of the alkaline-halo assay, which is based on the osmotically driven radial diffusion of single-stranded DNA fragments through agarose pores, is remarkably similar to that of the widely used alkaline elution and comet assays.

Peroxynitrite-mediated release of arachidonic acid from PC12 cells.

A short term exposure of PC12 cells to a concentration of tert‐butylhydroperoxide (tB‐OOH) causing peroxynitrite‐dependent DNA damage and cytotoxiticity promoted a release of arachidonic acid (AA) that was sensitive to phospholipase A2 (PLA2) inhibitors and insensitive to phospholipase C or diacylglycerol lipase inhibitors. The extent of AA release was also mitigated by nitric oxide synthase (NOS) inhibitors and peroxynitrite scavengers. Low levels (10u2003μM) of authentic peroxynitrite restored the release of AA mediated by tB‐OOH in NOS‐inhibited cells whereas concentrations of peroxynitrite of 20u2003μM, or higher, effectively stimulated a PLA2 inhibitor‐sensitive release of AA also in the absence of additional treatments. These results are consistent with the possibility that endogenous as well as exogenous peroxynitrite promotes activation of PLA2.

Direct excision of 50 kb pair DNA fragments from megabase-sized fragments produced during apoptotic cleavage of genomic DNA.

The DNA of U937 cells exposed to two different apoptotic stimuli, namely the cocktail H2O2/3‐aminobenzamide (3AB) and etoposide, was analyzed using field inversion gel electrophoresis (FIGE) as well as programmable, autonomously controlled electrode electrophoresis (PACE). The results obtained indicate that FIGE is not appropriate for sizing apoptotic DNA fragments. PACE appears to be more accurate and reliable and the results obtained with this technique strongly suggest that the 50 kb DNA fragments are directly excised from Mb‐sized DNA fragments without the intermediate cleavage of 200–300 kb products.

Cross-resistance to heavy metals in hydrogen peroxide-resistant CHO cell variants

Hydrogen peroxide-resistant Chinese hamster ovary (CHO) cells displayed cross-resistance to CdCl2, HgCl2 and NaAsO2 but not to Na2Cr2O7, ZnCl2, NiCl2 and CuSO4. Resistance to hydrogen peroxide and to the metals was partially retained by these cells for many generations despite growth in drug-free medium. The loss of resistance was a slow process, and was different for the various metal compounds. Cell variants had a slightly higher content of non-protein intracellular thiols (NPSH) than sensitive cells. This biochemical feature did not seem to be the cause of resistance to CdCl2 but accounted for at least part of the resistance to HgCl2 and NaAsO2. Increased metallothionein synthesis did not seem to be responsible for the metal-resistant phenotype. These results suggest that resistance to specific metal compounds in cultured mammalian cells adapted to hydrogen peroxide is dependent on a number of factors which differ for the various metal compounds and which are characterized by a different stability.

Morphological Changes in Escherichia coli Cells Exposed to Low or High Concentrations of Hydrogen Peroxide

Escherichia coli cells challenged with low or high concentrations of hydrogen peroxide are killed via two different mechanisms and respond with morphological changes which are also dependent on the extracellular concentration of the oxidant. Treatment with low concentrations (<2.5 mM) of H2O2 is followed by an extensive cell filamentation which is dependent on the level of H2O2 or the time of exposure. In particular, addition of 1.75 mM H2O2 results in a growth lag of approximately 90 min followed by partial increase in optical density, which was mainly due to the onset of the filamentous response. In fact, microscopic analysis of the samples obtained from cultures incubated with the oxidant for various time intervals has revealed that this change in morphology becomes apparent after 90 min of exposure to H2O2 and that the length of the filaments gradually increases following longer time intervals. Analysis of the ability of these cells to form colonies has indicated a loss in viability in the first 90 min of exposure followed by a gradual recovery in the number of cells capable of forming colonies. Measurement of lactate dehydrogenase in culture medium (as a marker for membrane damage) has revealed that a small amount of this enzyme was released from the cells at early times (< 150 min) but not after longer incubation periods (300 min). Cells exposed to high concentrations of H2O2 (>10 mM) do not filament and their loss of viability is associated with a marked reduction in cell volume. In fact, treatment with 17.5 mM H2O2 resulted in a time‐dependent decrease of the optical density, clonogenicity, and cellular volume. In addition, these effects were paralleled by a significant release in the culture medium of lactate dehydrogenase thus suggesting that the reduced cell volume may be dependent on membrane damage followed by loss of intracellular material. This hypothesis is supported by preliminary results obtained in electron microscopy studies. In conclusion, this study further demonstrates that the response of E. coli to hydrogen peroxide is highly dependent on the concentration of H2O2 and further stresses the point that low or high concentrations of the oxidant result in the production of different species leading to cell death via two different mechanisms and/or capable of specifically affecting the cell shape.

Sodium-dependent transport of ascorbic acid in U937 cell mitochondria.

U937 cells exposed to physiological concentrations of ascorbic acid (AA) accumulate the reduced form of the vitamin in the cytosol and even further in their mitochondria. In both circumstances, uptake was dependent on Na+‐AA‐cotransport, with hardly any contribution of hexose transporters, which might be recruited to transport the oxidized form of the vitamin. There was an identical linear relationship between the mitochondrial accumulation of the vitamin and the extramitochondrial AA concentration, regardless of whether detected in experiments using intact cells or isolated mitochondria. Western blot experiments revealed expression of both SVCT1 and 2 in plasma membranes, whereas SVCT2 was the only form of the transporter expressed at appreciable amounts in mitochondria. These results therefore provide the novel demonstration of SVCT2‐dependent mitochondrial transport of AA and hence challenge the present view that mitochondria only take up the oxidized form of the vitamin.