Primed T cells are more resistant to Fas-mediated activation-induced cell death than naive T cells.

Memory T cells respond in several functionally different ways from naive T cells and thus function as efficient effector cells. In this study we showed that primed T cells were more resistant to Fas-mediated activation-induced cell death (AICD) than naive T cells using OVA-specific TCR transgenic DO10 mice and Fas-deficient DO10 lpr/lpr mice. We found that apoptosis was efficiently induced in activated naive T cells at 48 and 72 h after Ag restimulation (OVA peptide; 0.3 and 3 microM), whereas apoptosis was not significantly increased in activated primed T cells at 24-72 h after Ag restimulation. We further showed that the resistance to AICD in primed T cells was due to the decreased sensitivity to apoptosis induced by Fas-mediated signals, but TCR-mediated signaling equally activated both naive and primed T cells to induce Fas and Fas ligand expressions. Furthermore, we demonstrated that primed T cells expressed higher levels of Fas-associated death domain-like IL-1beta-converting enzyme inhibitory protein (FLIP), an inhibitor of Fas-mediated apoptosis, at 24-48 h after Ag restimulation than naive T cells. In addition, Bcl-2 expression was equally observed between activated naive and primed T cells after Ag restimulation. Thus, these results indicate that naive T cells are sensitive to Fas-mediated AICD and are easily deleted by Ag restimulation, while primed/memory T cells express higher levels of FLIP after Ag restimulation, are resistant to Fas-mediated AICD, and thus function as efficient effector cells for a longer period.     

Neuronal cells but not muscle cells are resistant to oxidative stress mediated protein misfolding and cell death: Role of molecular chaperones

Our recent study in a mouse model of familial-Amyotrophic Lateral Sclerosis (f-ALS) revealed that muscle proteins are equally sensitive to misfolding as spinal cord proteins despite the presence of low mutant CuZn-superoxide dismutase, which is considered to be the key toxic element for initiation and progression of f-ALS. More importantly, we observed differential level of heat shock proteins (Hsp’s) between skeletal muscle and spinal cord tissues prior to the onset and during disease progression; spinal cord maintains significantly higher level of Hsp’s compared to skeletal muscle. In this study, we report two important observations; (i) muscle cells (but not neuronal cells) are extremely vulnerable to protein misfolding and cell death during challenge with oxidative stress and (ii) muscle cells fail to mount Hsp’s during challenge unlike neuronal cells. These two findings can possibly explain why muscle atrophy precedes the death of motor neurons in f-ALS mice.     

Collateral sensitivity: ABCG2-overexpressing cells are more vulnerable to oxidative stress

Multidrug resistance (MDR), which is the main obstacle to cancer chemotherapy, is mainly due to overexpression of ATP-binding cassette (ABC) transporters, especially ABCB1 (P-glycoprotein), ABCC1 (MRP1), and ABCG2 (BCRP). A novel idea to overcome MDR is that of collateral sensitivity, i.e., finding a treatment to which cells overexpressing ABC transporters are more sensitive than cells that do not overexpress them. In this study we demonstrate for the first time that MDCKII-BCRP cells, overexpressing ABCG2, are more vulnerable to exogenous oxidative stress induced by several oxidants, viz. paraquat, menadione, hydrogen peroxide, tert-butylperoxide, and 2,2-azobis(2-methylpropionamidine) dihydrochloride. MDCKII-BCRP cells have significantly decreased glutathione level and decreased activities of glutathione S-transferase and glutathione reductase, which may underlie their augmented vulnerability to oxidative stress. These results suggest the possibility of using agents that induce oxidative stress to selectively kill cells overexpressing BCRP.     

Actively phosphorylating mitochondria are more resistant to lactic acidosis than inactive mitochondria

Oxidative phosphorylation of isolated ratskeletal muscle mitochondria after exposure to lactic acidosis ineither phosphorylating or nonphosphorylating states has been evaluated.Mitochondrial respiration and transmembrane potential(_m) weremeasured with pyruvate and malate as the substrates. The addition oflactic acid decreased the pH of the reaction medium from 7.5 to 6.4. When lactic acid was added to nonphosphorylating mitochondria, thesubsequent maximal ADP-stimulated respiration decreased by 27%compared with that under control conditions(P < 0.05), and the apparentMichaelis-Menten constant(K_m) for ADPdecreased to 10 µM vs. 20 µM (P < 0.05) in controls. In contrast, maximal respiration and ADPsensitivity were not affected when mitochondria were exposed toacidosis during active phosphorylation in state 3. Acidosissignificantly increased mitochondrial oxygen consumption in state 4 (post-state 3), irrespective of when acidosis was induced. This effectof acidosis was attenuated in the presence of oligomycin. The additionof lactic acid during state 4 respiration decreased _m by 19%. The ratio betweenadded ADP and consumed oxygen (P/O) was close to the theoretical valueof 3 in all conditions. The addition of potassium lactate during state3 (i.e., medium pH unchanged) had no effect on the parameters measured.It is concluded that lactic acidosis has different effects when inducedon nonphosphorylating vs. actively phosphorylating mitochondria. On thebasis of these results, we suggest that the influence of lacticacidosis on muscle aerobic energy production depends on thephysiological conditions at the onset of acidity.

     

DNA fragmentation factor 45-deficient cells are more resistant to apoptosis and exhibit different dying morphology than wild-type control cells

The DNA fragmentation factor 45 (DFF45) is a subunit of a heterodimeric DNase complex critical for the induction of DNA fragmentation in vitro. To understand the in vivo role of DFF45 in programmed cell death, we measured the expression of DFF45 during mouse development and compared DNA fragmentation and viability of DFF45-deficient cells with wild-type control cells after activation of apoptosis. We found that DFF45 is ubiquitously expressed throughout mouse development. Moreover, DFF45-deficient thymocytes are resistant to DNA fragmentation with in vivo dexamethasone treatment. Furthermore, primary thymocytes from DFF45 mutant mice are also more resistant to apoptosis than wild-type control cells on exposure to several apoptotic stimuli. Dying DFF45-deficient thymocytes exhibit different morphology than wild-type control cells in that they show reduced degree of chromatin condensation, absent nuclear fragmentation, intranuclear cytoplasmic invagination, and striking nuclear chromatin conglutination after release from disintegrating cells. These results indicate that DFF45 is essential during normal apoptosis.     

Tetraploid citrus rootstocks are more tolerant to salt stress than diploid

Citrus trees are subject to several abiotic constraints such as salinity. Providing new rootstocks more tolerant is thus a requirement. In this article, we investigated salt stress tolerance of three tetraploid rootstock genotypes when compared to their respective diploid rootstocks (Poncirus trifoliata, Carrizo citrange, Cleopatra mandarin). Plant growth, leaf fall and ion contents were investigated. At the end of the experiment, leaf fall was observed only for diploid Poncirus trifoliata plants as well as chlorosis symptoms for Poncirus trifoliata and Carrizo citrange diploid plants. The diploid Cleopatra mandarin plants growth rate was not affected by salt stress and has even been increased for tetraploid Cleopatra mandarin. Ion contents investigation has shown lower accumulations of chloride ions in leaves of the tetraploid plants when compared to diploid plants. Our results suggest that citrus tetraploid rootstocks are more tolerant to salt stress than their corresponding diploid. To cite this article: B. Saleh et al., C. R. Biologies 331 (2008).     

Tyrphostins protect neuronal cells from oxidative stress

Tyrphostins are a family of tyrosine kinase inhibitors originally synthesized as potential anticarcinogenic compounds. Because tyrphostins have chemical structures similar to those of the phenolic antioxidants, we decided to test the protective efficacy of tyrphostins against oxidative stress-induced nerve cell death (oxytosis). Many commercially available tyrphostins, at concentrations ranging from 0.5 to 200 microm, protect both HT-22 hippocampal cells and rat primary neurons from oxytosis brought about by treatment with glutamate, as well as by treatment with homocysteic acid and buthionine sulfoximine. The tyrphostins protect nerve cells by three distinct mechanisms. Some tyrphostins, such as A25, act as antioxidants and eliminate the reactive oxygen species that accumulate as a result of glutamate treatment. These tyrphostins also protect cells from hydrogen peroxide and act as antioxidants in an in vitro assay. In contrast, tyrphostins A9 and AG126 act as mitochondrial uncouplers, collapsing the mitochondrial membrane potential and thereby reducing the generation of reactive oxygen species from mitochondria during glutamate toxicity. Finally, the third group of tyrphostins does not appear to be effective as antioxidants but rather protects cells by increasing the basal level of cellular glutathione. Therefore, the effects of tyrphostins on cells are not limited to their ability to inhibit tyrosine kinases.     

Glial cell type-specific responses to menadione-induced oxidative stress

Glial cell types in the central nervous system are continuously exposed to reactive oxygen species (ROS) due to their high oxygen metabolism and demonstrate differential susceptibility to certain pathological conditions believed to involve oxidative stress. The purpose of the current studies was to test the hypothesis that mtDNA damage could contribute to the differential susceptibility of glial cell types to apoptosis induced by oxidative stress. Primary cultures of rat astrocytes, oligodendrocytes, and microglia were utilized, and menadione was used to produce the oxidative stress. Apoptosis was detected and quantitated in menadione-treated oligodendrocytes and microglia (but not astrocytes) using either positive annexin-V staining or positive staining for 3'-OH groups in DNA. The apoptotic pathway that was activated involved the release of cytochrome c from the intermitochondrial space and activation of caspase 9. Caspase 8 was not activated after exposure to menadione in any of the cells. Using equimolar concentrations of menadione, more initial damage was observed in mtDNA from oligodendrocytes and microglia. Additionally, using concentrations of menadione that resulted in comparable initial mtDNA damage, more efficient repair was observed in astrocytes compared to either oligodendrocytes or microglia. The differential susceptibility of glial cell types to oxidative damage and apoptosis did not appear related to cellular antioxidant capacity, because under the current culture conditions astrocytes had lower total glutathione content and superoxide dismutase activity than oligodendrocytes and microglia. These results show that the differential susceptibility of glial cell types to menadione-induced oxidative stress and apoptosis appears to correlate with increased oxidative mtDNA damage and support the hypothesis that mtDNA damage could participate in the initiation of apoptosis through the enhanced release of cytochrome c and the activation of caspase 9.     

Peroxiredoxin-null yeast cells are hypersensitive to oxidative stress and are genomically unstable

Peroxiredoxins are a family of abundant peroxidases found in all organisms. Although these antioxidant enzymes are thought to be critically involved in cellular defense and redox signaling, their exact physiological roles are largely unknown. In this study, we took a genetic approach to address the functions of peroxiredoxins in budding yeast. We generated and characterized a yeast mutant lacking all five peroxiredoxins. The quintuple peroxiredoxin-null mutant was still viable, though the growth rate was lower under normal aerobic conditions. Although peroxiredoxins are not essential for cell viability, peroxiredoxin-null yeast cells were more susceptible to oxidative and nitrosative stress. In the complete absence of peroxiredoxins, the expression of other antioxidant proteins including glutathione peroxidase and glutathione reductase was induced. In addition, the quintuple mutant was hypersensitive to glutathione depletion. Thus, the glutathione system might cooperate with other antioxidant enzymes to compensate for peroxiredoxin deficiency. Interestingly, the peroxiredoxinnull yeast cells displayed an increased rate of spontaneous mutations that conferred resistance to canavanine. This mutator phenotype was rescued by yeast peroxiredoxin Tsa1p, but not by its active-site mutant defective for peroxidase activity. Our findings suggest that the antioxidant function of peroxiredoxins is important for maintaining genome stability in eukaryotic cells.     

All species are important,but some species are more important than others

Foundation species control biodiversity and ecosystem processes, but are difficult to identify. In this issue of the Journal of Vegetation Science, Elumeeva et al. show that Festuca varia and Nardus stricta act as foundation species in the Caucasus’ alpine. This paper augments the piecemeal literature on foundation species while highlighting the need for more comprehensive approaches to their identification and conservation.     

Sensitization of neuronal cells to oxidative stress with mutated human alpha-synuclein

Linkage of alpha-synuclein (alpha-SN) mutations to familial Parkinson's disease (PD) and presence of alpha-SN as a major constituent of Lewy body in both sporadic and familial PD implicate alpha-SN abnormality in PD pathogenesis. Here we demonstrate that overexpression of wild-type or mutant alpha-SN does not cause any deleterious effect on the growth or continued propagation of transfected human cells, but overproduction of mutant alpha-SN heightens their sensitivity to menadione-induced oxidative injury. Such enhanced vulnerability is more pronounced in neuronal transfectants than in their nonneuronal counterparts and is associated with increased production of reactive oxygen species. The data suggest that mutated alpha-SN, especially with an alanine-to-proline substitution at residue 30, sensitizes neuronal cells to oxidative damage.     

ARPE-19 retinal pigment epitheliaL CELLS are highly resistant to oxidative stress and exercise strict control over their lysosomal redox-active iron

Normal retinal pigment epithelial (RPE) cells are postmitotic, long-lived and basically not replaced. Daily, they phagocytose substantial amounts of lipid-rich material (photoreceptor outer segment discs), and they do so in the most oxygenated part of the body – the retina. One would imagine that this state of affairs should be associated with a rapid formation of the age pigment lipofuscin (LF). However, LF accumulation is slow and reaches significant amounts only late in life when, if substantial, it often coincides with or causes age-related macular degeneration. LF formation occurs inside the lysosomal compartment as a result of iron-catalyzed peroxidation and polymerization. This process requires phagocytosed or autophagocytosed material under degradation, but also the presence of redox-active low mass iron and hydrogen peroxide. To gain some information on how RPE cells are able to evade LF formation, we investigated the response of immortalized human RPE cells (ARPE-19) to oxidative stress with/without the protection of a strong iron-chelator. The cells were found to be extremely resistant to hydrogen peroxide-induced lysosomal rupture and ensuing cell death. This marked resistance to oxidative stress was not explained by enhanced degradation of hydrogen peroxide, but to a certain extent further increased by the potent lipophilic iron chelator SIH. The cells were also able to survive, and even replicate, at high concentrations of SIH and showed a high degree of basal autophagic flux. We hypothesize that RPE cells have a highly developed capacity to keep lysosomal iron in a non-redox-active form, perhaps by pronounced autophagy of iron-binding proteins in combination with an ability to rapidly relocate low mass iron from the lysosomal compartment.     

Common alien plants are more competitive than rare natives but not than common natives

Success of alien plants is often attributed to high competitive ability. However, not all aliens become dominant, and not all natives are vulnerable to competitive exclusion. Here, we quantified competitive outcomes and their determinants, using response‐surface experiments, in 48 pairs of native and naturalised alien annuals that are common or rare in Germany. Overall, aliens were not more competitive than natives. However, common aliens (invasive) were, despite strong limitation by intraspecific competition, more competitive than rare natives. This is because alien species had higher intrinsic growth rates than natives, and common species had higher intrinsic growth rates than rare ones. Strength of interspecific competition was not related to status or commonness. Our work highlights the importance of including commonness in understanding invasion success. It suggests that variation among species in intrinsic growth rates is more important in competitive outcomes than inter‐ or intraspecific competition, and thus contributes to invasion success and rarity.     

5'-nicked apurinic/apyrimidinic sites are resistant to beta-elimination by beta-polymerase and are persistent in human cultured cells after oxidative stress

Genomic DNA is continuously exposed to oxidative stress. Whereas reactive oxygen species (ROS) preferentially react with bases in DNA, free radicals also abstract hydrogen atoms from deoxyribose, resulting in the formation of apurinic/apyrimidinic (AP) sites and strand breaks. We recently reported high steady-state levels of AP sites in rat tissues and human liver DNA (Nakamura, J., and Swenberg, J. A. (1999) Cancer Res. 59, 2522-2526). These AP sites were predominantly cleaved 5' to the lesion. We hypothesized that these endogenous AP sites were derived from oxidative stress. In this investigation, AP sites induced by ROS were quantitated and characterized. A combination of H(2)O(2) and FeSO(4) induced significant numbers of AP sites in calf thymus DNA, which were predominantly cleaved 5' to the AP sites (75% of total aldehydic AP sites). An increase in the number of 5'-AP sites was also detected in human cultured cells exposed to H(2)O(2), and these 5'-AP sites were persistent during the post-exposure period. beta-Elimination by DNA beta-polymerase efficiently excised 5'-regular AP sites, but not 5'-AP sites, in DNA from cells exposed to H(2)O(2). These results suggest that 5'-oxidized AP sites induced by ROS are not efficiently repaired by the mammalian short patch base excision repair pathway.     

Mouse granulosa cells contribute more to the mRNA synthesis of mZP2 than oocyte does

In order to elucidate the biogenesis of mouse zona pellucida 2 (mZP2) protein, RT-PCR, and in situ hybridization were carried out to localize the expression of mouse ZP2 mRNA. Cumulus cells of the OCC (Oocyte-Cumulus cell Complex) were isolated from the oocytes after superovulation for the RNA extraction. The frozen sections of ovaries from adolescent and aged mice were prepared to hybridize with RNA probe of mouse ZP2. mRNA of ZP2 was detected in isolated cumulus cells by RT-PCR. Results of in situ hybridization showed that the mRNA of ZP2 was synthesized in both oocyte and granulosa cells at different folliculogenesis stages; and the expression of ZP2 mRNA in granulosa cells was stronger than that in oocyte; much weaker expression of mZP2 was detected in the follicles of aged mouse. These suggest that the entire amount of ZP2 mRNA generated in the granulosa cells layer should be much more than that in oocyte. Therefore, we think that the granulosa cells contribute more to the mZP2 mRNA synthesis than oocyte does.