Search for apoptotic nucleases in yeast: role of Tat-D nuclease in apoptotic DNA degradation

DNA fragmentation/degradation is an important step for apoptosis. However, in unicellular organisms such as yeast, this process has rarely been investigated. In the current study, we revealed eight apoptotic nuclease candidates in Saccharyomyces cerevisiae, analogous to the Caenorhabditis elegans apoptotic nucleases. One of them is Tat-D. Sequence comparison indicates that Tat-D is conserved across kingdoms, implicating that it is evolutionarily and functionally indispensable. In order to better understand the biochemical and biological functions of Tat-D, we have overexpressed, purified, and characterized the S. cerevisiae Tat-D (scTat-D). Our biochemical assays revealed that scTat-D is an endo-/exonuclease. It incises the double-stranded DNA without obvious specificity via its endonuclease activity and excises the DNA from the 3'- to 5'-end by its exonuclease activity. The enzyme activities are metal-dependent with Mg(2+) as an optimal metal ion and an optimal pH around 5. We have also identified three amino acid residues, His(185), Asp(325), and Glu(327), important for its catalysis. In addition, our study demonstrated that knock-out of TAT-D in S. cerevisiae increases the TUNEL-positive cells and cell survival in response to hydrogen hyperoxide treatment, whereas overexpression of Tat-D facilitates cell death. These results suggest a role of Tat-D in yeast apoptosis.     

A gibberellin-induced nuclease is localized in the nucleus of wheat aleurone cells undergoing programmed cell death

The aleurone layer of cereal grains undergoes a gibberellin-regulated process of programmed cell death (PCD) following germination. We have applied a combination of ultrastructural and biochemical approaches to analyze aleurone PCD in intact wheat grains. The terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling assay revealed that PCD was initiated in aleurone cells proximal to the embryo and then extended to distal cells. DNA fragmentation and terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling analysis revealed PCD of aleurone cells in maize grains, although the process was delayed as compared with wheat. Aleurone cells undergoing PCD showed a rapid vacuolation with high lytic activity in the cytoplasm, whereas the nucleus, which adopted an irregular shape, appeared essentially intact and showed symptoms of degradation at the end of the process. A nuclease activity was identified localized in the nucleus of aleurone cells undergoing PCD, just prior to the appearance of DNA laddering. This nuclease was induced by gibberellic acid treatment and was not detected when gibberellin synthesis was inhibited or in gibberellic acid-insensitive mutants. This nuclease was activated by Ca(2+) and Mg(2+), strongly inhibited by Zn(2+), and showed optimum activity at neutral pH, resembling nucleases involved in apoptosis of animal cells.     

Barley aleurone layers secrete a nuclease in response to gibberellic Acid : purification and partial characterization of the associated ribonuclease, deoxyribonuclease, and 3'-nucleotidase activities

Incubation of barley (Hordeum vulgare L. cv Himalaya) half-seeds with gibberellic acid enhances the secretion of ribonuclease and deoxyribonuclease from aleurone tissue (MJ Chrispeels, JE Varner 1967 Plant Physiol 42: 398-406; L Taiz, JE Starks 1977 Plant Physiol 60: 182-189). These activities were over 50-fold greater in medium of half-seeds incubated with gibberellic acid than in control medium. Ribonuclease and deoxyribonuclease activities initially appeared in the medium 24 to 48 hours after hormone induction and increased for up to 96 hours. Both activities had a pH optimum of 6.0 and a temperature optimum of 55°C. When the medium from gibberellic acid-treated half-seeds was analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis, the major ribonuclease and deoxyribonuclease activity bands comigrated. The two enzyme activities remained associated throughout a 2,700-fold purification employing ammonium sulfate fractionation, Heparin-Agarose affinity chromatography, and Reactive Blue 2-Agarose affinity chromatography. Also accompanying the ribonuclease and deoxyribonuclease activities throughout purification was the ability to hydrolyze the 3′-phosphoester linkage of 3′-AMP. The purified protein was composed of a single polypeptide with an apparent molecular weight of 36 kilodaltons as determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis. It is concluded that in response to gibberellic acid, barley aleurone tissue secretes a nuclease having ribonuclease, deoxyribonuclease, and 3′-nucleotidase activities.     

Resistance of mitochondrial DNA to degradation characterizes the apoptotic but not the necrotic mode of human leukemia cell death

Cell death can occur by two basically different processes. The original term, necrosis, is now reserved for the generally destructive series of events which include the release of lysosomal enzymes and loss of cell membrane integrity. In contrast, mild treatment with cell damaging agents, or withdrawal of growth factors, may result in a characteristic form of degradation of cellular DNA which is associated with cell death that has morphology known as apoptosis. In this study human leukemia cells were exposed to agents or conditions previously reported to cause necrosis or apoptosis, monitored by detection of DNA “ladders,” and the integrity of cellular DNA was determined on Southern blots. Nuclear DNA was distinguished from mitochondrial DNA by use of probes specific for nuclear genes or for mitochondrial DNA. When HL60, K562, MOLT4, or U937 cells were exposed to conditions which resulted in necrosis, mitochondrial DNA was damaged at approximately the same rate as nuclear DNA, but in apoptosis mtDNA was not degraded. Thus, the ratio of the relative (to untreated cells) abundance of mitochondrial DNA measured by a probe for 16S mitochondrial ribosomal RNA on Southern blots, to the relative abundance of DNA of any nuclear gene, was 1 or less in necrosis, but rose to values greater than 2 in apoptosis. It is concluded that the comparison of the degree of fragmentation of mitochondrial and nuclear DNA provides a quantitative way of distinguishing necrosis from apoptosis.     

Characterization of nuclease activities and DNA fragmentation induced upon hypersensitive response cell death and mechanical stress

Programmed cell death (PCD) is activated during the response of multicellular organisms to some invading pathogens. One of the key aspects of this process is the degradation of nuclear DNA which is thought to facilitate the recycling of DNA from dead cells. The PCD of tobacco plants (genotype NN) infected with tobacco mosaic virus (TMV) is accompanied by the induction of nuclease activities and the cleavage of nuclear DNA to fragments of about 50 kb. We examined the correlation between the increase in nuclease activities and the fragmentation of nuclear DNA during TMV- and bacteria-induced PCD in tobacco. We found that the increase in nuclease activities did not always correlate with fragmentation of nuclear DNA. Thus, in addition to pathogens that induce PCD, mechanical injury and infiltration of leaves with 1 M sucrose or bacteria that did not induce PCD also resulted in an increase in nuclease activities. Analysis of nuclease activities in total leaf extracts, nuclear extracts, and intercellular fluid (i.e., apoplast) revealed that at least four different nuclease activities are induced during PCD in tobacco; of these at least three appear to be secreted into the intercellular fluid. Although the latter were also induced in response to treatments that did not result in DNA fragmentation, they may function in the recycling of plant DNA during late stages of PCD when the integrity of the plasma membrane is compromised. This suggestion is supported by the finding that DNA degradation occurred late during TMV-induced PCD in tobacco. In addition, the finding of induced nuclease activities in the intercellular fluid raises the possibility that they may serve a protective function by degrading the DNA of invading pathogens.     

Botrytis cinerea BcNma is involved in apoptotic cell death but not in stress adaptation

Apoptotic-like programmed cell death (PCD) occurs naturally in fungi during development and might also be induced by external conditions. Candidate apoptotic genes have been characterized in several model fungal species but not in plant pathogenic fungi. Here we report on the isolation and characterization of BcNMA, an orthologue of the human pro-apoptotic gene HtrA2 from the plant pathogen Botrytis cinerea. The predicted BcNma protein shows high homology to the previously characterized Nma111p from Saccharomyces cerevisiae and despite some structural differences it complemented the function of Nma111p in Δnma111 mutant strains. BcNMA-over-expression and mutant strains had enhanced or reduced appearance of apoptotic markers, respectively. However there was no difference in growth response of the wild type and BcNMA-transgenic strains to application of various stresses, and the effect on pathogenicity was marginal in both the over-expression and mutant strains. When considered together these results suggest that although BcNma has a pro-apoptotic activity, it is not a major regulator of apoptosis. The protein probably has additional roles that are unrelated to apoptosis, which lead to the pleotrophic phenotype of the transgenic strains and lack of a clear effect on stress adaptation and pathogenicity.     

Purification and characterization of a Bacillus subtilis 168 nuclease, YokF, involved in chromosomal DNA degradation and cell death caused by thermal shock treatments

We purified and characterized a 39-kDa Bacillus subtilis 168 nuclease that has been suggested in this laboratory to be involved in chromosomal DNA degradation induced by lethal heat and cold shock treatments in vivo. The nuclease activity was inhibited in vitro by aurintricalboxylic acid but not by Zn(2+). By the mutant analysis, we identified the 39-kDa nuclease as a product of yokF gene. The yokF gene contained a putative lipoprotein signal peptide motif. After in vivo exposure to lethal heat and cold stresses, the chromosomal DNA fragmentation was reduced in the yokF mutant, which demonstrated about a 2-10-fold higher survival rate than the wild type. The yokF mutant was found to be more sensitive to mitomycin C than the wild type. The transformation efficiency of the yokF mutant was about 10 times higher than that of the wild type. It is suggested that when B. subtilis cells are exposed to a stressful thermal shock resulting in membrane perturbation, YokF nuclease consequently dislocates into the cytoplasm and then attacks DNA.     

Caspase-2 promotes cytoskeleton protein degradation during apoptotic cell death

The caspase family of proteases cleaves large number of proteins resulting in major morphological and biochemical changes during apoptosis. Yet, only a few of these proteins have been reported to selectively cleaved by caspase-2. Numerous observations link caspase-2 to the disruption of the cytoskeleton, although it remains elusive whether any of the cytoskeleton proteins serve as bona fide substrates for caspase-2. Here, we undertook an unbiased proteomic approach to address this question. By differential proteome analysis using two-dimensional gel electrophoresis, we identified four cytoskeleton proteins that were degraded upon treatment with active recombinant caspase-2 in vitro. These proteins were degraded in a caspase-2-dependent manner during apoptosis induced by DNA damage, cytoskeleton disruption or endoplasmic reticulum stress. Hence, degradation of these cytoskeleton proteins was blunted by siRNA targeting of caspase-2 and when caspase-2 activity was pharmacologically inhibited. However, none of these proteins was cleaved directly by caspase-2. Instead, we provide evidence that in cells exposed to apoptotic stimuli, caspase-2 probed these proteins for proteasomal degradation. Taken together, our results depict a new role for caspase-2 in the regulation of the level of cytoskeleton proteins during apoptosis.     

Control of apoptotic DNA degradation

Apoptotic DNA degradation has been thought to be a cell-autonomous process. Recent evidence suggests that heterophagic recognition and engulfment of dying cells by non-apoptotic cells may be critical for the activation and/or action of apoptogenic DNases.     

Conformational diseases and ER stress-mediated cell death: apoptotic cell death and autophagic cell death

The expanded polyglutamine (polyQ) tracts observed in autosomal dominant neurodegenerative disorders have the tendency to form intracellular aggregates, thus enhancing apoptotic cell death and the formation of autophagic vesicles. PolyQ accumulation inhibits the ER-associated degradation system (ERAD) resulting in reduced retrotranslocation from the ER and increased accumulation of misfolded proteins in the lumen of ER. Autophagy is an early cellular defense mechanism associated with ER stress, but prolonged ER stress may induce autophagic cell death, with destruction of cellular components and apoptotic cell death. Endoplasmic reticulum (ER) stress may be the key signal for both of these events.     

An age-related increase in resistance to DNA damage-induced apoptotic cell death is associated with development of DNA repair mechanisms

Neurons in the developing brain die via apoptosis after DNA damage, while neurons in the adult brain are generally resistant to these insults. The basis for this resistance is a matter of conjecture. We report here that cerebellar granule neurons (CGNs) in culture lose their competence to die in response to DNA damage as a function of time in culture. CGNs at either 1 day in vitro (DIV) or 7 DIV were treated with the DNA damaging agents camptothecin, UV or gamma-irradiation and neuronal survival measured. The younger neurons were effectively killed by these agents, while the older neurons displayed a significant resistance to killing. Neuronal survival did not change with time in culture when cells were treated with C2-ceramide or staurosporine, agents which do not target DNA. The resistance to UV irradiation developed over time in culture and was not due to changes in mitotic rate. Increases in DNA strand breakage, up-regulation of the levels of both p53 and its phosphorylated form and nuclear translocation of p53 were equivalent in both older and younger neurons, indicating a comparable p53 stress response. In addition, we show that treatment of older neurons with pharmacological inhibitors of distinct components of the DNA repair machinery promotes the accumulation of DNA damage and sensitizes these cells to the toxic effects of UV exposure. These data demonstrate that older neurons appear to be more proficient in DNA repair in comparison to their younger counterparts, and that this leads to increased survival after DNA damage.     

Barley aleurone cell development: molecular cloning of aleurone-specific cDNAs from immature grains

The cloning of 11 different homology groups of cDNAs representing genes expressed in aleurone, but not in starchy endosperm of 20-day-old barley grains is described. Among the cDNAs, four are aleurone-specific, while the remaining are also expressed in the embryo, but not in any other part of the plant.Sequence analysis of one of the aleurone-specific clones, B11E, reveals an open reading frame coding for an unidentified 10.4 kDa protein with a putative signal sequence and a possible metal-binding finger. The B11E gene has a high GC content in the 5 leader sequence (63%), as well as in the coding region (70%) compared to known cDNAs from the barley starchy endosperm. Northern analysis of B11E indicates maximum mRNA abundance around mid-phase of grain development.When isolated immature aleurone/pericarp is incubated in tissue culture medium (MS) the B11E message disappears, indicating a requirement for a diffusible factor from the intact grain for its continued presence.     

DNA topoisomerase IIalpha interacts with CAD nuclease and is involved in chromatin condensation during apoptotic execution

Apoptotic execution is characterized by dramatic changes in nuclear structure accompanied by cleavage of nuclear proteins by caspases (reviewed in [1]). Cell-free extracts have proved useful for the identification and functional characterization of activities involved in apoptotic execution [2-4] and for the identification of proteins cleaved by caspases [5]. More recent studies have suggested that nuclear disassembly is driven largely by factors activated downstream of caspases [6]. One such factor, the caspase-activated DNase, CAD/CPAN/DFF40 [4,7,8] (CAD) can induce apoptotic chromatin condensation in isolated HeLa cell nuclei in the absence of other cytosolic factors [6,8]. As chromatin condensation occurs even when CAD activity is inhibited, however, CAD cannot be the sole morphogenetic factor triggered by caspases [6]. Here we show that DNA topoisomerase IIalpha (Topo IIalpha), which is essential for both condensation and segregation of daughter chromosomes in mitosis [9], also functions during apoptotic execution. Simultaneous inhibition of Topo IIalpha and caspases completely abolishes apoptotic chromatin condensation. In addition, we show that CAD binds to Topo IIalpha, and that their association enhances the decatenation activity of Topo IIalpha in vitro.     

Active oxygen and cell death in cereal aleurone cells

The cereal aleurone layer is a secretory tissue whose function is regulated by gibberellic acid (GA) and abscisic acid (ABA). Aleurone cells lack functional chloroplasts, thus excluding photosynthesis as a source of active oxygen species (AOS) in cell death. Incubation of barley aleurone layers or protoplasts in GA initiated the cell death programme, but incubation in ABA delays programmed cell death (PCD). Light, especially blue and UV-A light, and H(2)O(2) accelerate PCD of GA-treated aleurone cells, but ABA-treated aleurone cells are refractory to light and H(2)O(2) and are not killed. It was shown that light elevated intracellular H(2)O(2), and that the rise in H(2)O(2) was greater in GA-treated cells compared to cells in ABA. Experiments with antioxidants show that PCD in aleurone is probably regulated by AOS. The sensitivity of GA-treated aleurone to light and H(2)O(2) is a result of lowered amounts of enzymes that metabolize AOS. mRNAs encoding catalase, ascorbate peroxidase and superoxide dismutase are all reduced during 6-18 h of incubation in GA, but these mRNAs were present in higher amounts in cells incubated in ABA. The amounts of protein and enzyme activities encoded by these mRNAs were also dramatically reduced in GA-treated cells. Aleurone cells store and metabolize neutral lipids via the glyoxylate cycle in response to GA, and glyoxysomes are one potential source of AOS in the GA-treated cells. Mitochondria are another potential source of AOS in GA-treated cells. AOS generated by these organelles bring about membrane rupture and cell death.     

Modulated kinase activities in cells undergoing tumour necrosis factor-induced apoptotic cell death

Tumour necrosis factor-alpha (TNF) has a variety of cellular effects including apoptotic and necrotic cytotoxicity. TNF activates a range of kinases, but their role in cytotoxic mechanisms is unclear. HeLa cells expressing elevated type II 75 kDa TNF receptor (TNFR2) protein, analysed by flow cytometry and Western analysis, showed altered c-Jun N-terminal kinase (JNK) and p38 mitogen-activated protein kinase (p38MAPK; but not MAPK) protein content and activation. There was greater JNK activation, but reduced p38MAPK activation in dying cells compared to those still to enter TNF-induced apoptosis. Moreover, cells displaying more rapid apoptosis possess higher levels of type I 55 kDa TNFR1 receptor isoform, but less TNFR2. These findings reveal differential kinase activation in TNF-induced apoptotic death.     

Compromised proteasome degradation elevates neuronal nitric oxide synthase levels and induces apoptotic cell death

The significance of impairment of proteasome activity in PC12 cells was examined in connection with nitrative/nitrosative stress and apoptotic cell death. Treatment of differentiated PC12 cells with MG132, a proteasome inhibitor, elicited a dose- and time-dependent increase in neuronal nitric oxide synthase (nNOS) protein levels, decreased cell viability, and increased cytotoxicity. Viability and cytotoxicity were ameliorated by L-NAME (a broad NOS inhibitor). Nitric oxide/peroxynitrite formation was increased upon treatment of PC12 cells with MG132 and decreased upon treatment with the combination of MG132 and 7-NI (a specific inhibitor of nNOS). The decreases in cell viability appeared to be effected by an activation of JNK and its effect on mitochondrial Bcl-x_L phosphorylation. These effects are strengthened by the activation of caspase-9 along with increased caspase-3 activity upon treatment of PC12 cells with MG132. These results suggest that impairment of proteasome activity and consequent increases in nNOS levels lead to a nitrative stress that involves the coordinated response of JNK cytosolic signaling and mitochondrion-driven apoptotic pathways.     

Mitochondrial regulation of apoptotic cell death

Mitochondria play a decisive role in the regulation of both apoptotic and necrotic cell death. Permeabilization of the outer mitochondrial membrane and subsequent release of intermembrane space proteins are important features of both models of cell death. The mechanisms by which these proteins are released depend presumably on cell type and the nature of stimuli. Of the mechanisms involved, mitochondrial permeability transition appears to be associated mainly with necrosis, whereas the release of caspase activating proteins during early apoptosis is regulated primarily by the Bcl-2 family of proteins. However, there is increasing evidence for interaction and co-operation between these two mechanisms. The multiple mechanisms of mitochondrial permeabilization may explain diversities in the response of mitochondria to numerous apoptotic stimuli in different types of cells.     

Identification and characterization of nuclease activities in anaerobic environmental samples

DNA-degrading activity from anaerobic samples of bovine ruminal fluid, primary anaerobic digestor wastewater, freshwater sediments, and marine sediments was observed in the presence of 5 mM EDTA. Nuclease activity experiments involved exposing salmon chromosomal DNA to the environmental samples in 50 mM pH 7.2 buffer, incubating at 37 degrees C, and subjecting the products to electrophoresis. The same stock and concentration of EDTA used in these assays (5 mM) completely inhibited commercial grade DNase. Nuclease activity in two of the samples, ruminal fluid and wastewater, was further characterized. DNA degradation in the ruminal sample was significantly reduced when EDTA or citrate concentrations were increased to 50 mM or above. DNA degradation activity in ruminal fluid was associated with material that passed through a 0.22-micron filter, but wastewater activity was associated with material retained by a 3-micron filter. Degradation activity in the wastewater was resistant to heat pretreatment, whereas the rumen activity was heat-labile (70 degrees C, 60 min). These results demonstrated the biochemical complexity of these two environments and that high molecular weight DNA has a short half-life in these anaerobic environments.     

alpha-Amylase and programmed cell death in aleurone of ripening wheat grains

Late maturity alpha-amylase (LMA) in wheat is a genetic defect that may result in the accumulation of unacceptable levels of high pI alpha-amylase in grain in the absence of germination or weather damage. During germination, gibberellin produced in the embryo triggers expression of alpha-Amy genes, the synthesis of alpha-amylase and, subsequently, cell death in the aleurone. LMA also involves the aleurone and whilst LMA appears to be independent of the embryo there is nevertheless some evidence that gibberellin is involved. The aim of this investigation was to determine whether the increase in alpha-amylase activity in LMA-prone genotypes, like alpha-amylase synthesis by aleurone cells in germinating or GA-challenged grains, is followed by aleurone cell death. Programmed cell death was seen in aleurone layers from developing, ripe and germinated grains using confocal microscopy and fluorescent probes specific for dead or living cells. Small pockets of dying cells were observed distributed at random throughout the aleurone of ripening LMA-affected grains and by harvest-ripeness these cells were clearly dead. The first appearance of dying cells, 35 d post-anthesis, coincided with the later part of the 'window of sensitivity' in grain development in LMA-prone wheat cultivars. No dead or dying cells were present in ripening or fully ripe grains of control cultivars. In germinating grains, dying cells were observed in the aleurone adjacent to the scutellum and, as germination progressed, the number of dead cells increased and the affected area extended further towards the distal end of the grain. Aside from the obvious differences in spatial distribution, dying cells in 20-24 h germinated grains were similar to dying cells in developing LMA-affected grains, consistent with previous measurements of alpha-amylase activity. The increase in high pI alpha-amylase activity in developing grains of LMA-prone cultivars, like alpha-amylase synthesis in germinating grains, is associated with cell death, providing further evidence for the involvement of gibberellin in the LMA response.