Abstract
Oxidative stress is a state in which the accumulation of reactive oxygen species exceeds the capacity of cellular antioxidant systems. Both apoptosis and necrosis are observed under oxidative stress, and we have reported that these two forms of cell death are induced in H2O2-stimulated HeLa cells depending on the concentration of H2O2. Weak H2O2 stimulation induces apoptosis, while strong H2O2 stimulation induces necrosis. However, the detailed mechanisms controlling the switching between these forms of cell death depending on the level of oxidative stress remain elusive. Here, we found that NAD+ metabolism is a key factor in determining the form of cell death in H2O2-stimulated HeLa cells. Under both weak and strong H2O2 stimulation, intracellular nicotinamide adenine dinucleotide (NAD+) was depleted to a similar extent by poly (ADP-ribose) (PAR) polymerase 1 (PARP1)-dependent consumption. However, the intracellular NAD+ concentration recovered under weak H2O2 stimulation but not under strong H2O2 stimulation. NAD+ recovery was mediated by nicotinamide (NAM) phosphoribosyltransferase (NAMPT)-dependent synthesis via the NAD+ salvage pathway, which was suggested to be impaired only under strong H2O2 stimulation. Furthermore, downstream of NAD+, the dynamics of the intracellular ATP concentration paralleled those of NAD+, and ATP-dependent caspase-9 activation via apoptosome formation was thus impaired under strong H2O2 stimulation. Collectively, these findings suggest that NAD+ dynamics balanced by PARP1-dependent consumption and NAMPT-dependent production are important to determine the form of cell death activated under oxidative stress.
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Introduction
Apoptosis and necrosis are the most typical classifications of the forms of cell death, and a prominent difference between these forms of cell death is plasma membrane integrity [1]. In general, apoptosis is not accompanied by plasma membrane collapse, and apoptotic cells are actively removed by phagocytosis in the organism [2, 3]. On the other hand, necrosis is accompanied by plasma membrane disruption, resulting in leakage of intracellular molecules such as damage-associated molecular patterns (DAMPs). Since DAMPs are potent activators of inflammatory responses, necrosis is a more proinflammatory form of cell death than apoptosis [4]. Although normal inflammation is critical for biological defense systems, excess inflammation often causes disease [5, 6]. For example, pyroptosis, a type of regulated necrosis induced by bacterial infection, activates the immune system to remove pathogens via the release of intracellular molecules [7,8,9,10]. On the other hand, excessive necrosis leads to pathogenic inflammation, resulting in exacerbation of certain disorders, such as liver disease [11,12,13]. Therefore, proper selection of the cell death form is critical for maintaining an organism’s homeostasis.
The mechanisms underlying the switching of cell death between apoptosis and necrosis have been reported in several contexts. Necroptosis, another type of regulated necrosis, is induced as an alternative to apoptosis when caspase-8 is inhibited under TNFα stimulation [14, 15]. It has also been reported that the preexisting intracellular ATP concentration is critical in determining the form of cell death induced by the Fas ligand and hypoxia [16,17,18]. These studies showed that intracellular ATP is required for the induction of apoptosis and that necrosis is induced when the intracellular ATP supply is exhausted. This switch in the form of cell death might manifest as the appearance of necrotic cells mixed with apoptotic cells in areas with a decreased concentration of ATP in vivo, such as the center of solid tumors and ischemic tissues.
We have previously reported that weak oxidative stress induces apoptosis, whereas strong oxidative stress induces necrosis in HeLa cells. Strong oxidative stress-induced necrosis was mediated by the ASK1-p38-NR4A2 signal transduction [19]. However, the detailed mechanisms controlling the switch between the form of cell death depending on the strength of oxidative stress remain elusive. Here, we investigated the forms of cell death induced under various levels of oxidative stress and found that the NAMPT-dependent NAD+ metabolism under oxidative stress is a crucial factor determining the form of cell death. We also found that the dynamics of the intracellular ATP concentration paralleled those of NAD+, which is important for triggering the intrinsic apoptotic pathway through cleavage of caspase-9 and -3 under weak oxidative stress.
Results
Intracellular ATP recovers only under weak H2O2 stimulation
We reported in a previous study that the form of cell death can be switched from apoptosis to necrosis by increasing the concentration of H2O2 in HeLa cells [19]. To estimate the threshold of H2O2 concentration for the switch from apoptosis to necrosis, we examined the effects of various concentrations of H2O2 and detected necrosis and apoptosis by measuring LDH release (30 h after stimulation) and caspase-3 activity (10 h after stimulation), respectively (Fig. 1A). LDH release was simply increased in an H2O2 concentration-dependent manner, and the percentage of LDH release in response to stimulation with 1.1 mM H2O2 was approximately 70% (Fig. 1A, B). On the other hand, caspase-3 activity peaked in response to stimulation with 0.7–0.8 mM H2O2, and the percentage of LDH release was less than 20% under this treatment (Fig. 1A). Caspase-3 activity started to decrease at 0.9 mM H2O2 and further decreased along with concentrations over 0.9 mM, becoming even lower than that in the basal state (Fig. 1A, C). To evaluate the induction of apoptosis by another method, HeLa cells were stained with Annexin V FITC at 20 h after exposure to 0.7 or 1.1 mM H2O2 [20]. Staurosporine (STS) treatment was used as a positive control for apoptosis induction. The ratio of Annexin V FITC-positive cells was increased in cells treated with 0.7 mM H2O2 to an extent comparable to that observed in STS-treated cells. On the other hand, consistent with caspase-3 activity, the number of Annexin V FITC-positive cells was low after 1.1 mM H2O2 stimulation (Fig. 1D, E). Collectively, these results suggest that 0.7 mM H2O2 stimulation mainly induces apoptosis, while 1.1 mM H2O2 stimulation mainly induces necrosis in HeLa cells.
Previous studies have suggested that the form of cell death in response to certain stimuli is affected by the intracellular ATP concentration; apoptosis is induced when the preexisting intracellular ATP concentration is high, whereas the same stimuli induce necrosis when the intracellular ATP concentration is low [16, 18]. Therefore, we examined the concentration of intracellular ATP at various time points under 0.7 mM and 1.1 mM H2O2 stimulation (Fig. 1F). Under both 0.7 and 1.1 mM H2O2 stimulation, the ATP concentration sharply decreased immediately after stimulation (approximately 1 h after stimulation: early phase). However, the ATP concentration gradually recovered under 0.7 mM stimulation but not under 1.1 mM stimulation. These results suggest that the ATP concentration at the late phase (after 6 h) of stimulation may be a key determinant of the form of cell death under H2O2 stimulation.
Intercellular NAD+ is consumed by PARP1 in both weak and strong H2O2 stimulation, but it recovers only in the late phase of weak stimulation
Previous reports have shown that DNA-damaging stimuli decrease the intracellular ATP concentration through poly (ADP-ribose) (PAR) polymerase 1 (PARP1) activation [21, 22]. PARP1 synthesizes PAR from NAD+ [23]. Although PARP1 activity is essential for DNA repair, overactivation of PARP1 by excessive DNA damage causes depletion of NAD+ [24]. Since NAD+ is an important coenzyme in ATP generation, NAD+ depletion results in a low-energy state and necrotic cell death [21, 22, 25]. PARP1-dependent necrotic cell death is called parthanatos [26]. It has been reported that PARP1 is also activated by oxidative stress [27, 28]. Thus, we examined whether the ATP decline under H2O2 stimulation is related to NAD+ consumption by PARP1 (Fig. 2A, B). Treatment with a PARP1 inhibitor, DPQ, partially prevented the acute decreases in NAD+ and ATP at 1 h under 1.1 mM H2O2 stimulation. No further decrease was observed thereafter, and the state was kept up to 10 h after stimulation (Fig. 2A, B), indicating that PARP1 is required for NAD+ and ATP exhaustion under H2O2 stimulation. As it was suggested that the intracellular ATP concentration in the late phase of stimulation may determine the form of cell death under H2O2 stimulation (Fig. 1F), we evaluated the effect of PARP1 inhibition on the form of cell death under 1.1 mM H2O2 stimulation. Consistent with the dynamics of ATP concentration under oxidative stress revealed by us and others [27], PARP1 inhibition not only suppressed LDH release but also increased caspase-3 activity upon stimulation with 1.1 mM H2O2 (Fig. 2C, D). Moreover, PARP1 depletion by siRNA resulted in the suppression of LDH release and the recovery of caspase-3 activity (Fig. 2E–G). These results suggest that NAD+ consumption by PARP1 affects both early and late ATP concentration up to 10 h and thus regulates the decision between apoptotic and necrotic cell death under H2O2 stimulation. It has been reported that not only depletion of NAD+ but also translocation of apoptosis-inducing factor (AIF) from mitochondria to the nucleus is mediated by activation of PARP1 to execute parthanatos [26, 29,30,31,32,33]. However, AIF knockdown did not affect necrosis induction by 1.1 mM H2O2 stimulation (Supplementary Fig. S1A and B), suggesting that AIF may not be involved in the necrosis induced by 1.1 mM H2O2 stimulation.
Since the dynamics of ATP in the late phase of H2O2 stimulation differed depending on the concentration of H2O2, we compared the dynamics of NAD+ under weak and strong H2O2 stimulation (Fig. 2H). Similar to the ATP dynamics, both 0.7 and 1.1 mM H2O2 decreased the NAD+ concentration in the early phase of the stimulation, whereas the NAD+ concentration recovered only in the late phase of 0.7 mM stimulation. These results suggest that the dynamics of intracellular NAD+ is the dominant determinant of the dynamics of intracellular ATP at least under H2O2 stimulation, and that the NAD+ concentration in late phase but not that in early phase determines the form of cell death.
The NAMPT-dependent NAD+ salvage pathway is necessary for the recovery of NAD+ and induction of apoptosis under weak H2O2 stimulation
The intracellular NAD+ concentration is controlled by the balance between NAD+ consumption and production. Therefore, we next examined whether the rate of consumption and/or synthesis of NAD+ is altered depending on the strength of H2O2 stimulation. Since the NAD+ consumption in the early phase of H2O2 stimulation depends at least in part on PARP1 (Fig. 2A) which is activated by DNA damage, we compared the extent of DNA damage in response to 0.7 mM and 1.1 mM H2O2 stimulation by monitoring γH2AX. We found that the γH2AX intensity under 1.1 mM H2O2 was higher than that under 0.7 mM H2O2 at 6 and 10 h after stimulation (Fig. 3A), suggesting that 1.1 mM H2O2 stimulation induced stronger DNA damage than 0.7 mM stimulation. Then, we examined whether PARP1 activity is also increased in strong H2O2 stimulation by monitoring the accumulation of PARylated proteins (Fig. 3B). Under both 0.7 mM and 1.1 mM H2O2 stimulation, however, the observed accumulation of PARylated proteins was similar soon after stimulation (15 min) and decreased thereafter. The amount of PARylated protein was comparable between the 0.7 and 1.1 mM H2O2 stimulation conditions at all time points examined. The result suggested that the NAD+ consumption by PARP1 may not largely differ between 0.7 mM and 1.1 mM H2O2 stimulations.
We next focused on NAD+ production under oxidative stress. A major NAD+ synthesis system is the NAD+ salvage pathway, in which nicotinamide (NAM) phosphoribosyltransferase (NAMPT) is a rate-limiting enzyme (Fig. 3C) [34, 35]. Treatment with the NAMPT inhibitor FK866 almost completely suppressed the recovery of NAD+ upon 0.7 mM H2O2 stimulation (Fig. 3D), suggesting that NAD+ recovery relies on the NAMPT-dependent salvage pathway. Consistent with the NAD+ dynamics, FK866 treatment abolished ATP recovery under 0.7 mM H2O2 stimulation (Fig. 3E). Moreover, FK866 treatment enhanced LDH release and reciprocally suppressed caspase-3 activity even under 0.7 mM H2O2 stimulation (Fig. 3F, G), suggesting that FK866 treatment changed the form of cell death from apoptosis to necrosis by inhibiting NAD+ recovery under 0.7 mM H2O2 stimulation.
The NAD+ salvage pathway consists of two steps: (1) NAMPT-dependent nicotinamide mononucleotide (NMN) synthesis from NAM and phosphoribosyl diphosphate (PRPP) and (2) nicotinamide mononucleotide adenylyltransferase (NMNAT)-dependent NAD+ synthesis from NMN and ATP (Fig. 3C) [34, 35]. Administration of nicotinamide riboside (NR) increases the intracellular NAD+ concentration even under NAMPT-deficient conditions, because NMN can be synthesized from NR by NR kinase (NRK) (Fig. 3C) [36]. Thus, we treated cells with NR under 1.1 mM H2O2 stimulation to investigate whether NMNAT is functional even under strong oxidative stress. In cells treated with NR, NAD+ recovery was observed at 10 h after 1.1 mM H2O2 stimulation (Fig. 3H). NR treatment also rescued ATP recovery in the late phase (Fig. 3I), suppressed LDH release and increased caspase-3 activity in response to 1.1 mM H2O2 stimulation (Fig. 3J, K). These results indicate that NR treatment switches the form of cell death from necrosis to apoptosis via the recovery of intracellular NAD+ and ATP under strong oxidative stress. That is, although NMNAT is functional even under 1.1 mM H2O2 stimulation, a shortage of NMN caused by impairment of upstream system of the NAD+ salvage pathway leads to the failure of NAD+ recovery.
To investigate what upstream step is impaired in the NAD+ salvage pathway under 1.1 mM stimulation, we first examined the protein level of NAMPT by immunoblotting. The intracellular NAMPT level did not change by either weak or strong H2O2 stimulation (Fig. 3A). To examine NAMPT activity, we established a HeLa cell line that stably expressed Flag-tagged NAMPT. The cells were exposed to 0.7 or 1.1 mM H2O2 for 3 or 6 h, and Flag-NAMPT was immunoprecipitated. Then, the activity of purified NAMPT was measured by an in vitro assay. Unexpectedly, NAMPT activity did not change in response to stimulation with either concentration of H2O2 (Fig. 3L). Therefore, impairment of the NAD+ salvage pathway under strong oxidative stress is not attributable to a decrease in either the amount or activity of NAMPT, but instead to some other reasons, e.g., deficiency of NAMPT substrates, such as PRPP (Fig. 3C).
Caspase-9 cleavage was impaired under strong oxidative stress
Finally, we sought to determine why ATP recovery correlates with apoptosis induction. Two major apoptotic pathways have been defined, namely, the extrinsic and intrinsic pathways [37]. The extrinsic pathway is induced through death receptor signaling and is dependent on caspase-8 as the initiator caspase. On the other hand, the intrinsic pathway is induced by various types of stress, including DNA damage and ER stress. In the intrinsic pathway, caspase-9 functions as the initiator caspase. To investigate which pathway is involved in the apoptosis induced by 0.7 mM H2O2 stimulation, we established caspase-8, -9 and -3 knockout HeLa cell lines by the CRISPR/Cas9 system. Caspase-3 activity was increased by 0.7 mM H2O2 stimulation in WT and caspase-8 knockout cells, whereas it was abolished in caspase-9 knockout cells (Fig. 4A), suggesting that apoptosis induction by 0.7 mM H2O2 stimulation is mediated by the caspase-9-dependent intrinsic pathway, as reported previously [38]. The intrinsic pathway consists of several molecular steps: (1) cyt c release from mitochondria; (2) apoptosome formation with cyt c, Apaf1 and caspase-9; (3) cleavage and activation of caspase-9 in the apoptosome; and (4) cleavage and activation of caspase-3 by activated caspase-9 [37]. Cleavage of each caspase under oxidative stress was monitored by immunoblotting (Fig. 4B). In WT HeLa cells, both caspase-3 and -9 were cleaved upon 0.7 mM H2O2 stimulation, but these cleavage events were impaired under 1.1 mM H2O2 stimulation, suggesting that the upstream step of caspase-9 cleavage is abrogated under strong oxidative stress. Cleavage of caspase-3 and -9 was detected in caspase-8 knockout HeLa cells, but caspase-3 cleavage was diminished in caspase-9 knockout cells under 0.7 mM H2O2 stimulation. Although caspase-3 is known to be a downstream caspase of caspase-9, caspase-3 knockout abolished caspase-9 cleavage, suggesting the existence of a positive feedback loop between caspase-3 and caspase-9 in 0.7 mM H2O2-induced apoptosis. Although caspase-8 cleavage was slightly detected in WT cells stimulated with 0.7 mM H2O2, caspase-8 cleavage had a negligible contribution to the induction of apoptosis, because caspase-8 knockout had no effect on caspase-3 activity (Fig. 4A) or cleavage of caspase-3 (Fig. 4B).
Events upstream of caspase-9 cleavage include cyt c release from mitochondria, apoptosome formation, and apoptosome activation. Among these events, apoptosome activation is known to require ATP or dATP [39]. Therefore, ATP recovery may be important for apoptosome activation. Consistent with this idea, cleavage of caspase-9 was detected after 6 h of 0.7 mM H2O2 stimulation (Fig. 4C), corresponding well to the time point when ATP recovery was observed (Fig. 1F). Collectively, these results suggest that strong H2O2 stimulation does not induce apoptosis because of the lack of ATP recovery after H2O2 stimulation, which impairs apoptosome activation and caspase-9 cleavage (Fig. 5).
Discussion
In this study, we demonstrated that intracellular NAD+ and ATP dynamics regulated by the NAD+ salvage pathway were key factors in determining the form of cell death in H2O2-stimulated HeLa cells. Previous reports have shown that the preexisting intracellular ATP concentration alters the form of cell death induced by some stimuli, including Fas and hypoxia [16, 18]. In this report, we demonstrated that the dynamics of the intracellular ATP concentration during H2O2 stimulation differed between the apoptosis-inducing weak stimulation and the necrosis-inducing strong stimulation (Fig. 1F). In both weak and strong H2O2 stimuli, the ATP concentration decreased immediately after stimulation. However, the ATP concentration recovered in the late phase of weak but not strong H2O2 stimulation, suggesting that the ATP concentration in the late phase (after 6 h) but not in the early phase (after approximately 1 h) of stimulation determines the final form of cell death. The reason that the ATP concentration in the late phase determines the form of cell death may be attributed to the mechanism of apoptosis induction. We demonstrated that caspase-3 activation under weak oxidative stress required caspase-9 but not caspase-8, suggesting that the intrinsic pathway of apoptosis is responsible (Fig. 4A). Among the molecular mechanisms of the intrinsic pathway, activation of the apoptosome for caspase-9 cleavage has been reported to require ATP or dATP [39]. Consistent with this idea, caspase-9 cleavage was impaired under strong H2O2 stimulation, during which the intracellular ATP was completely depleted until 10 h after stimulation (Fig. 4B). Our speculation was further supported by the finding that cleavage of caspase-9 was observed only in the late phase (>6 h) of weak H2O2 stimulation when the intracellular ATP concentration had recovered (Fig. 4C).
We showed that the dynamics of NAD+ paralleled those of ATP under H2O2 stimulation (Fig. 2H). In HeLa cells, H2O2 stimulation decreased the intracellular NAD+ concentration in a PARP1 activity-dependent manner (Fig. 2A). Similar to the ATP concentration, the NAD+ concentration gradually recovered only under weak H2O2 stimulation (Fig. 2H). The result suggests that the strength of H2O2 stimulation affects NAD+ recovery, which eventually leads to the difference in the ATP concentration and thus the form of cell death. Consistent with this observation, inhibition of NAD+ depletion by a PARP1 inhibitor prevented ATP depletion (Fig. 2A, B) and changed the form of cell death from necrosis to apoptosis under strong H2O2 stimulation (Fig. 2C, D). Previous reports showed that DNA-damaging stimuli induce necrotic cell death in a PARP1-dependent manner, a phenomenon called parthanatos [26]. In this study, we exhibited a tight correlation between the switch of the form of cell death and NAD+ dynamics in H2O2-stimulated HeLa cells. Whether this NAD+ dynamics-dependent switching system can be applied to other parthanatos-inducing stimuli is an interesting question. Since parthanatos is known to associate with various diseases, such as neurodegenerative diseases and ischemia-reperfusion injury [26], it is important to examine the generality of cell death form switching by the intracellular NAD+ and ATP concentrations in other context of parthanatos.
Regarding the difference of NAD+ dynamics under weak and strong H2O2 stimulation, there are two factors that affect the intracellular NAD+ concentration: the rate of consumption and the rate of synthesis. A major NAD+-consuming enzyme in the early phase of H2O2 stimulation was PARP1, because the PARP1 inhibitor substantially suppressed the NAD+ depletion in the early phase of H2O2 stimulation (Fig. 2A). Therefore, difference in PARP1 activity could affect the intracellular NAD+ dynamics. However, the PARP1 activity showed no apparent difference between weak and strong H2O2 stimulation at any time points (Fig. 3B), suggesting that the speed of NAD+ consumption by PARP1 may not be largely affected by the concentrations of H2O2 used in this study. These data implied that the rate of NAD+ synthesis rather than the rate of NAD+ consumption may be different depending on the strength of H2O2 stimulation in the late phase. In this study, we found that NAD+ recovery under weak H2O2 stimulation was mediated by the NAMPT-dependent NAD+ salvage pathway (Fig. 3D). In addition, we found that NR treatment, which can increase the NAD+ concentration in an NMNAT-dependent but NAMPT-independent manner, recovered the NAD+ concentration 10 h after strong H2O2 stimulation (Fig. 3H). These data suggested that the NMNAT-dependent step is intact but upstream step, such as NAMPT-dependent step, is suppressed under strong H2O2 stimulation. Under NR treatment, recovery of intracellular ATP began earlier than that of NAD+ (Fig. 3H, I). The result seems contradictory to the idea that NAD+ is required to produce ATP. However, although the difference was not statistically significant, the concentration of intracellular NAD+ in NR-treated samples was slightly higher than that in control samples after 6 h of 1.1 mM H2O2 stimulation (Fig. 3H). Since NAD+ functions as a coenzyme for ATP generation, NAD+ itself is not consumed during ATP generation. Therefore, it is possible that even a small amount of NAD+ might be sufficient to recover the ATP concentration under strong H2O2 stimulation.
Because the NAMPT-dependent step was a plausible determinant whether to recover NAD+ under H2O2 stimulation, we compared the NAMPT protein amount and activity in H2O2-stimulated HeLa cells. However, neither the amount of intracellular NAMPT protein nor the activity of purified NAMPT changed upon stimulation with any concentration of H2O2 (Fig. 3A, L), implying that the amounts of other component(s), such as NAMPT substrates, may be different depending on the strength of H2O2 stimulation. Further analysis of the NAMPT-dependent step is needed to elucidate the reasons that the dynamics of the intracellular NAD+ concentration differ depending on the strength of H2O2 stimulation; this knowledge will clarify a new molecular mechanism by which cells perceive the strength of H2O2 stimulation.
Oxidative stress-induced cell death is reported to be involved in many kinds of disorders, including neurodegenerative diseases, ischemia-reperfusion injury, liver disorders and cancer [12, 40, 41]. Since these diseases are affected by the inflammatory milieu, which is exacerbated by necrotic cell death, the proper control of the form of cell death based on our findings in the present study (manipulation of NAD+ recovery) would provide a treatment strategy for these diseases. In support of this idea, previous studies showed that an increase in the intracellular ATP concentration prevented progression of neurodegenerative diseases in a mouse model [42,43,44,45,46]. In this study, using HeLa cells, we demonstrated the threshold of switching the form of cell death fell around 1 mM H2O2, which is relatively high for physiological conditions [47]. It is considerable that other non-tumor cells, like primary neurons might show lower switching threshold, according to resistance to oxidative stress. Further analysis is important to investigate the variety of the switching threshold depending on cells, comparing with their capacity of the NAD+ salvage pathway. Collectively, our findings indicate the importance of a NAD+ recovery system to determine the form of cell death under oxidative stress and provide a new target for manipulating the NAD+ and ATP concentration as a potential strategy for the treatment of oxidative stress-related disorders.
Materials and methods
Cell lines and cell culture
HeLa cells and HeLa cells with KO of each caspase were cultured in DMEM-low glucose (Sigma, Cat#D6046) supplemented with 10% fetal bovine serum (FBS). HeLa cells stably expressing Flag-NAMPT or GFP were cultured in DMEM-low glucose supplemented with 10% FBS and 1 μg/mL puromycin (Thermo Fisher Scientific, Cat#A11138-03). HEK293T cells were cultured in DMEM-high glucose (Sigma, Cat#D5796) supplemented with 10% FBS. All cells were cultured in 5% CO2 at 37 °C and verified to be negative for mycoplasma contamination.
Caspase-3, -8 and -9 knockout HeLa cells were generated using the CRISPR/Cas9 system. To create the KO vectors, we used the following sets of DNA oligonucleotides.
Caspase-3 #1
CACCGTACCCGGGTTAACCGAAAGG and AAACCCTTTCGGTTAACCCGGGTAC
Caspase-3 #2
CACCGTCTTACCCGGGTTAACCGAA and AAACTTCGGTTAACCCGGGTAAGAC
Caspase-8 #1
CACCGAACGAGATATATCCCGGATG and AAACCATCCGGGATATATCTCGTTC
Caspase-8 #2
CACCGTCCGGGATATATCTCGTTTG and AAACCAAACGAGATATATCCCGGAC
Caspase-9 #1
CACCGCCGCCGATCCGCTTCGTCCA and AAACTGGACGAAGCGGATCGGCGGC
Caspase-9 #2
CACCGACAATCTTCTCGACCGACAC and AAACGTGTCGGTCGAGAAGATTGTC
Each set of DNA oligonucleotides was annealed in TE buffer by incubation at 95 °C for 5 min and subsequently at 60 °C for 5 min. Annealed DNA was then inserted into PX459 (Addgene, Cat#62988) digested with BbsI.
HeLa cells were transfected with PX459 containing separate sgRNAs targeting each caspase with Lipofectamine 2000 (Thermo Fisher Scientific, Cat#11668019) according to the manufacturer’s protocols with minor optimization. To reduce cytotoxicity, the cell culture medium was replaced with fresh medium 6 h after transfection. Two days after transfection, the medium was changed to puromycin-containing medium (1 μg/mL) and incubated for two more days. Then, polyclonal KO cells were seeded onto 10 cm dishes at a low density without puromycin for picking of single clones. Single clones of each caspase KO cell line were confirmed by immunoblotting.
To establish HeLa cells with stable expression of Flag-NAMPT or GFP, each cDNA was cloned into a pLenti CMV/TO Puro DEST (670-1) (Addgene, Cat#17293) plasmid, and lentiviral transduction was performed. Briefly, to produce lentivirus, HEK293T cells were transfected with the constructed plasmids, pCMV-VSV-G (Addgene, Cat#8454), and psPAX2 (Addgene, Cat#12260) using Lipofectamine 3000 (Thermo Fisher Scientific, Cat#L3000015), according to the manufacturer’s protocols with minor optimization. To reduce cytotoxicity, the cell culture medium was replaced with fresh medium 4 h after transfection. Lentivirus-containing culture supernatants were collected at 48 h post transfection and filtered through a 0.45 μm pore size filter (Millipore, Cat#SLHV033RS). HeLa cells were seeded into 24-well plates (5 × 104 cells/well) in medium supplemented with 10 μg/mL polybrene (Nacalai Tesque, Cat#17736-44), and the cells were transduced with lentiviral vectors overnight. The next day, the culture medium was replaced with fresh medium containing puromycin (1 μg/mL) for selection of transduced cells.
Antibodies
For the immunoblotting experiment, we used the following antibodies: rabbit monoclonal anti-PARP1 antibody (EPR18461: abcam, Cat#ab191217, 1/5000), mouse monoclonal anti-Actin antibody (AC-40: Sigma, Cat#A3853, 1/10000), rat monoclonal anti-α-tubulin antibody (YL1/2: Santa Cruz Biotechnology, Cat#sc-53029, 1/20000), rabbit polyclonal anti-PAR antibody (Enzo Life Science, ALX-210-890A-0100, 1/5000), rabbit polyclonal anti-NAMPT antibody (BETHYL, Cat#A300-372A, 1/10000), rabbit polyclonal anti-caspase-3 antibody (Cell Signaling, Cat#9662, 1/2000), mouse monoclonal anti-caspase-8 antibody (1C12: Cell Signaling, Cat#9746, 1/2000), mouse monoclonal anti-caspase-9 antibody (C9: Cell Signaling, Cat#9508, 1/2000), rabbit polyclonal anti-AIF antibody (Cell Signaling, Cat#4642, 1/5000), mouse monoclonal anti-Histone H2AX antibody (322105: R&D SYSTEMS, Cat#MAB3406, 1/1000) and rabbit polyclonal anti-γH2AX antibody (abcam, Cat#ab2893, 1/1000). We also used a horse anti-mouse IgG, HRP-linked antibody (Cell Signaling, Cat#7076); a goat anti-rabbit IgG, HRP-linked antibody (Cell Signaling, Cat#7074); and a goat anti-rat IgG, HRP-linked antibody (Cell Signaling, Cat#7077).
H2O2 stimulation
Two days before stimulation, cells were seeded in 6-, 24-, or 96-well culture plates (2 × 105, 5 × 104 or 1 × 104 cells/well, respectively). 1.5 h prior to stimulation, the culture medium was replaced with 2 mL, 500 μL or 100 μL of fresh medium, respectively. DPQ (Cayman, Cat#14450, 50 μM), FK866 (Sigma, Cat#F8557, 10 nM), NR (Carbosynth, Cat#NN15702, 1 mM) or vehicle control (DMSO ( ≥ 99.5% purity: Sigma, Cat#D5879) or H2O) was administered at the same time. DPQ and FK866 were diluted with DMSO to 50 mM and 10 μM, respectively. NR was diluted with H2O to 1 M. H2O2 (FUJIFILM Wako, Cat# 081-04215) was diluted to 100× the final concentration with H2O, and the diluted H2O2 was added to the culture medium at 20, 5 or 1 μL/well for 6-, 24-, or 96-well culture plates, respectively.
LDH assay
Necrosis induction was measured using an LDH Cytotoxicity Assay (FUJIFILM Wako, Cat#299-50601). Culture medium was collected 30 h after H2O2 stimulation and centrifuged for 3 min at 400 × g (medium sample). Cells were lysed with PBS containing 0.1% Triton X-100, and the cell lysate was then centrifuged for 10 min at 17,700 × g (lysate sample). The medium and lysate samples were individually mixed with reagents in 96-well microplates, and the absorbance was measured at 570 nm using a Varioskan Flash (Thermo Fisher Scientific) after incubation for approximately 5 min at room temperature. Necrosis induction was evaluated by calculating LDH release (%) as follows: (absorbance (abs) of medium samples − background)/((abs of lysate samples − background) + (abs of medium samples − background)).
Caspase-3 activity assay
Apoptosis induction was measured using a fluorogenic substrate for activated caspase-3, Ac-DEVD-AFC (Cayman, Cat#14459). Cells were lysed with PBS containing 0.1 % Triton X-100 10 h after H2O2 stimulation, and the cell lysate was centrifuged for 10 min at 17,700 × g. Lysate samples were individually mixed with reagents in 384-well microplates (15 μL of lysate sample, 25 μL of 2 × Reaction Buffer (Bio Vision, Cat#1068), 7.25 μL of PBS, 2.5 μL of caspase-3 substrate (1 mM in DMSO) and 0.25 μL of 1 M dithiothreitol (TCI, Cat#D1071)). Fluorescence signals were measured at specific wavelengths (Ex/Em = 400/505 nm) using a Varioskan Flash after incubation for approximately 90 min at 37 °C. For normalization, the protein amount in each lysate sample was measured using a DCTM protein assay (Bio-Rad, Cat#5000113, #5000114, #5000115). Caspase-3 activity in each sample was calculated as follows: ((fluorescence intensity of sample − background)/protein concentration of sample (μg/μL)). In Figs. 2D, 3G, K, caspase-3 activity in each sample was normalized to caspase-3 activity induced by 0.7 mM H2O2 without any treatment under the same experimental conditions (data not shown in the figure). In Fig. 2G, caspase-3 activity induced by 0.7 mM H2O2 without any knockdown treatment was used for normalization (data not shown in the figure). Finally, we defined the arbitrary unit (A.U.) by dividing each caspase activity value by the average caspase-3 activity in the technical replicates of the control sample under stimulation with 0.7 mM H2O2.
Annexin V staining
Apoptotic cells were stained with Annexin V-FITC (Nacalai Tesque, Cat#15342). Twenty-four hours after H2O2 or STS (FUJIFILM Wako, Cat#197-10251) stimulation, the medium was changed to new medium containing 50 μL of Annexin V-FITC (1/200) and Hoechst 33342 (DOJINDO, Cat#H342, 1/1000), and the cells were incubated for 30 min in 5% CO2 at 37 °C. The ratio of Annexin V-FITC-positive cells was calculated with the CellInsight NXT platform (Thermo Fisher Scientific).
Gene silencing by siRNA transfection
Knockdown experiments with siRNA were carried out by reverse transfection using Lipofectamine RNAiMAX (Thermo Fisher Scientific, Cat#13778150) and Opti-MEM (Thermo Fisher Scientific, Cat#31985) according to the manufacturer’s protocol. The final concentrations of PARP1 and AIF siRNA were 0.2 nM and 0.25 nM, respectively. The PARP1 siRNAs were purchased from Dharmacon (siGENOME Human PARP1 (142) siRNA #1 (D-006656-03-0010), target sequence: GCAACAAACUGGAACAGAU and siGENOME Human PARP1 (142) siRNA #2 (D-006656-04-0010), target sequence: GAAGUCAUCGAUAUCUUUA), and the AIF siRNAs were purchased from Thermo Fisher Scientific (Stealth siRNA Human AIF #1, target sequence: GGGUUAAGGUGAUGCCCAAUGCUAU and Stealth siRNA Human AIF #2, target sequence: GGAGUCAGCAGUGGCAAGUUACUUA). siGENOME Nontargeting siRNA #1 (Dharmacon) and Stealth siRNA Negative Control Medium GC Duplex #1 (Thermo Fisher Scientific) were used as controls. Each experiment was performed 2 days after transfection.
Cell lysis and immunoblotting
In Figs. 2E, 4B, C and S1A, cells seeded in 24-well plates were lysed with 100 μL/well lysis buffer (10 mM EDTA (pH 8.0), 150 mM NaCl, 20 mM Tris–HCl (pH 7.5), 1% sodium deoxycholate, 1% Triton X-100, 1 mM phenylmethylsulfonyl fluoride, and 5 µg/mL leupeptin). Cell extracts were centrifuged for 10 min at 17,700 × g, and supernatants were prepared by adding 2 × SDS sample buffer (80 µg/mL bromophenol blue, 10 mM dithiothreitol, 28.8% glycerol, 4% SDS and 80 mM Tris-HCl (pH 8.8)) and boiling at 98 °C for 3 min.
In Fig. 3A, B, cells seeded in 24-well plates were lysed with 100 μL/well 2 × SDS sample buffer heated to 98 °C. Cell extracts were boiled at 98 °C for 3 min and sonicated with an Ultra Sonic Homogenizer UH-50 (SMT).
Proteins were resolved by SDS-PAGE and electroblotted onto Immobilon-P membranes (Millipore, Cat#IPVH00010). The membranes were blocked with 2.5% skim milk (Megmilk Snow Brand) in TBS-T (137 mM NaCl, 20 mM Tris-HCl (pH 8.0) and 0.1% Tween 20) and probed with the appropriate primary antibodies diluted in primary antibody dilution buffer (TBS-T supplemented with 5% BSA (Iwai Chemicals, Cat#A001) and 0.1% NaN3 (Nacalai Tesque, Cat#312-33)) overnight. After replacing the primary antibody solution and probing the membranes with the appropriate HRP-conjugated secondary antibodies diluted with 2.5% skim milk in TBS-T, antibody-antigen complexes were detected on X-ray films (FUJIFILM, Cat#47410-26615 or Cat#47410-22617) or with a FUSION Solo S imaging system (VILBER) using ECL reagents (GE Healthcare). Representative data are shown in the figures, and more than two additional experimental replicates showed similar results. The images of uncropped gels are shown in Supplementary Fig. 2. Quantification was performed via densitometry using Fusion Capt software (VILBER).
ATP assay
The intracellular ATP concentration was measured using “Cell” ATP Assay reagent Ver. 2 (FUJIFILM Wako, Cat#381-09306). After H2O2 stimulation in a 96-well white plate (Corning, Cat#353377), the medium was removed, and 50 μL of ATP reaction mixture (1:1 medium: assay reagent) was added. Samples were incubated at room temperature in the dark for 10 min, and luminescence was measured using a Varioskan Flash. The ATP amount in each sample was calculated as follows: (luminescence of each sample–background). The relative ATP concentrations in Figs. 2B, 3E, I were calculated by comparison to the ATP amount at 1.5 h after the medium change (that is, 0 h of stimulation without any treatment). Finally, we defined the A.U. by dividing each ATP concentration by the average ATP concentration in the technical replicates of the control sample at 0 h.
NAD± assay
The intracellular NAD+ concentration was measured using an Amplite Fluorimetric Total NAD and NADH Assay Kit (AAT Bioquest, Cat#15257). After H2O2 stimulation, cells were lysed with PBS containing 0.1% Triton X-100 and 1 mM nicotinamide (TCI, N0078), and the cell lysate was then centrifuged for 10 min at 17,700 × g. Lysate samples were individually mixed with reagents in 384-well microplates (15 μL of lysate sample and 15 μL of NAD/NADH working solution), and fluorescence was measured at specific wavelengths (Ex/Em = 540/590 nm) using a Varioskan Flash approximately 30 min after incubation at room temperature. For normalization, the protein amount in each lysate sample was measured using a DCTM protein assay. The NAD+ amount in each sample was calculated as follows: ((fluorescence intensity of sample–background)/protein concentration of sample (μg/μL)). The relative NAD+ concentrations in Figs. 2A, 3D, H were calculated by comparison to the NAD+ amount at 1.5 h after the medium change (0 h of stimulation without any treatment). Finally, we defined the A.U. by dividing each NAD+ concentration by the average NAD+ concentration in the technical replicates of the control sample at 0 h.
NAMPT assay
NAMPT activity was measured using a CycLex NAMPT Colorimetric Assay Kit Ver. 2 (Cat#CY-1251V2). HeLa cells stably expressing Flag-NAMPT or GFP were seeded into 6-well plates. Two days after seeding, cells were stimulated with H2O2 and lysed with 500 μL/well lysis buffer (20 mM Tris (pH 8.0), 250 mM NaCl, 1 mM EDTA, 1 mM EGTA, 1% Triton X-100, 1 mM phenylmethylsulfonyl fluoride, and 5 µg/mL leupeptin). Cell extracts were centrifuged for 10 min at 17,700 × g, and the protein concentrations in the supernatants were measured using a DCTM protein assay. A 450 μL aliquot from the sample with the lowest protein concentration was transferred to a new tube. Other samples were also transferred to new tubes according to each protein concentration to equalize the total protein amount to that in the sample with the lowest concentration. The samples were diluted to 450 μL with lysis buffer. The diluted samples were incubated with anti-FLAG antibody beads (FUJIFILM Wako, clone 1E6, Cat#016-22784) for 1 h at 4 °C. The beads were washed with lysis buffer three times before use, and 20 μL of the bead suspension (50% slurry in lysis buffer) was used for immunoprecipitation. After incubation, the beads were washed twice with lysis buffer and twice with PBS, followed by direct addition of the reaction mix (total 90 μL: 5 μL of #1, 3.6 μL of #2 to #9, 56.2 μL of H2O; #1 to #9 are reagents provided in the NAMPT assay kit). Then, the samples were incubated at 1200 rpm and 30 °C using a ThermoMixer C (Eppendorf). At 30, 60, 90 and 120 min after the start of incubation, 20 μL of the reaction mix supernatants was aliquoted into 384-well microplates, and the absorbance was measured at 450 nm using a Varioskan Flash. Reaction mix without the supernatant was used as the sample at 0 min of incubation. After incubation, the remaining beads were prepared by adding 50 μL of 2 × SDS sample buffer and boiling at 98 °C for 3 min. The amount of NAMPT in the samples was quantified by immunoblotting as described above. NAMPT activity in each sample was calculated as follows: ((abs of each sample at 120 min–abs at 0 min)/band density of NAMPT in the corresponding sample determined by immunoblotting). Relative NAMPT activity was calculated by comparison to the NAMPT activity at 1.5 h after the medium change (0 h of stimulation). Finally, we defined the A.U. of NAMPT activity by dividing each NAMPT activity value by the average NAMPT activity in the technical replicates of the sample stimulated with 0 mM H2O2.
Statistical analysis
All data are presented as the mean ± SEM values. The numbers of samples, sample sizes, and statistical tests are indicated in the figure legends. The investigators were not blinded to the group allocation during the experiment. Statistical tests were performed using GraphPad Prism 7.0c or excel, and P < 0.05 was considered statistically significant. All experiments that are subjected to statistical analysis have more than three samples in each condition. Unpaired two-tailed Student’s t-test, unpaired two-tailed Welch’s t-test, one-way ANOVA followed by Dunnett’s multiple comparisons test, one-way ANOVA followed by the Tukey-Kramer multiple comparisons test, two-way ANOVA followed by the Sidak correction for multiple comparisons, or two-way ANOVA followed by Dunnett’s multiple comparisons test was used in this study. F-test was performed before t-test to estimate the variances between group of data. Throughout: *P < 0.05, **P < 0.01, ***P < 0.001 and ****P < 0.0001.
Data availability
All data generated or analyzed during this study are included in this published article and its supplementary information files.
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Acknowledgements
We thank all the current and previous members of the Laboratory of Cell Signaling for valuable materials and meaningful discussion.
Funding
This work was supported by the Japan Science and Technology Agency (JST) under the Moonshot R&D-MILLENNIA program (Grant number JPMJMS2002-18 to HI); by the Japan Agency for Medical Research and Development (AMED) under the Project for Elucidating and Controlling Mechanisms of Aging and Longevity (grant number JP20gm5010001 to HI); by the Japan Society for the Promotion of Science (JSPS) under the Grant-in-Aid for Scientific Research on Innovative Areas (KAKENHI; grant number JP17H06419 to IN), the Grant-in-Aid for Scientific Research (KAKENHI; grant numbers JP18H03995, JP18K19469 to HI, JP18H02569 to IN) and the Grant-in-Aid for JSPS Fellows (KAKENHI; grant number JP19J13520 to TN); by the Yakugaku-shinkoukai Foundation; and by the Naito Grant for the advancement of natural science.
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IN and HI conceived and supervised this project. TN designed and performed most of the experiments. TN, IN, and HI wrote the manuscript. All authors contributed to the discussion and the design of the research and commented on the manuscript.
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Nishida, T., Naguro, I. & Ichijo, H. NAMPT-dependent NAD+ salvage is crucial for the decision between apoptotic and necrotic cell death under oxidative stress. Cell Death Discov. 8, 195 (2022). https://doi.org/10.1038/s41420-022-01007-3
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DOI: https://doi.org/10.1038/s41420-022-01007-3
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