1. Introduction

Pancreatic ductal adenocarcinoma (PDAC) is the most common type of pancreatic cancer and the third cause of cancer death in both sexes. PDAC has almost the same number of diagnoses (496,000) as deaths (466,000), making it the most lethal type of cancer [1]. To date, surgical resection is the preferred method to overcome PDAC. On the one hand, tumors originating in the Vater ampulla, bile duct, or head of the pancreas are managed with a pancreatoduodenectomy (Whipple procedure). On the other hand, tumors located in the tail or body of the pancreas are surgically removed by a pancreatectomy performed distally and some cases require a total pancreatectomy [2]. Regrettably, despite the options for surgical resection, the 5-year survival rate is 25%. Moreover, this rate remains at 10% when there are no surgical resection options [3,4,5].

PDAC has a characteristic mutational profile, where mutations in the genes KRAS, cyclin-dependent kinase inhibitor 2A (CDKN2A), tumor protein p53 (TP53) and SMAD family member 4 (SMAD4) stand out [6,7]. The identification of germline mutations associated with PDAC may have major implications for treatment and familiar genetic screening. Up to 20% of patients could harbor germline/somatic mutations in genes associated with DNA damage repair (DDR), such as BRCA1, BRCA2, PALB2, CHECK2 and ATM [6]. Pathogenic somatic or germline mutations in BRCA1/2 lead to homologous recombination repair deficit and increase the sensitivity to agents that generate crosslinks in DNA strands, such as platinum bases therapies [8].

Accumulating molecular data allows the distinction of PDAC according to molecular subtype. Bailey and colleagues differentiated four molecular subtypes of PDAC, which could lead to an improvement in the accuracy of possible future treatment [9].

In routine clinical practice, patients are categorized into three groups according to their prognosis: patients with resectable, borderline resectable or metastatic PDAC [10]. Within the resectable group, patients have to receive adjuvant chemotherapy to avoid disease relapse, which is very frequent [11,12]. Regarding the metastatic group, the most effective treatments are FOLFIRINOX and the gemcitabine plus nab-paclitaxel scheme [10]. No current data on clinical trials comparing these two treatments are available. But the effectiveness of these alternatives has been reported to be similar in a comparative study [13]. In the recent NAPOLI-3 clinical trial, the combination of liposomal irinotecan, 5-FU/leucovorin and oxaliplatin (NALIRIFOX) has improved survival of patients compared to gemcitabine plus nab-paclitaxel in OS (11.1 months vs. 9.2 months) and PFS (7.4 months vs. 5.6 months) [14].

PDAC is also characterized by an immunosuppressive tumor microenvironment (TME). Tumor-associated macrophages can raise the number of myeloid-derived suppressor cells, also known as MDSCs, which subsequently contribute to local immunosuppression [15]. Another characteristic of PDAC is that it is surrounded by a dense stroma (desmoplasia) that constricts the vasculature, limiting oxygen and drug delivery to the tumor [16,17]. The combination of the genetic profile and the hostile TME make the solid pancreatic tumor with the lowest 5-year survival rate [1]. Given the immunosuppressive environment of PDAC, restoring immunogenic capacity is a possible therapeutic target. One of these immunotherapies is against CD40, a tumor necrosis factor receptor superfamily member in macrophages, which is responsible for modulating the activation of the T-cell. Activated CD40 has been linked to the orchestration of antitumor responses [18,19,20]. Another novel approach is the development of vaccines against cancer. The GVAX vaccine consists of a whole-cell vaccine that has been transfected with the granulocyte–macrophage colony-stimulating factor acting as a maturation factor for dendritic cells. The GVAX vaccine in combination with chemoradiotherapy has been used after surgery. The vaccine showed a disease-free survival benefit of 24.8 months (95% CI, 21.2–31.6) in the GVAX group compared to 17.3 months (95% CI, 14.6–22.8) in the control group [21]. Both conventional and novel therapies are still not fully effective. Therefore, new approaches must be developed.

In this context, a new therapeutic outlook is to induce iron-dependent cell death in combination with conventional chemotherapy. Iron-dependent cell death is a type of non-apoptotic regulated cell death called ferroptosis. It is characterized by an accumulation of lipid peroxides in cell membranes [22]. Ferroptosis can occur when the cellular antioxidant systems—such as glutathione peroxidase (GPX)—glutathione (GSH)—that prevent ferroptosis are surpassed by reactive oxygen species (ROS) [23]. ROS are considered a by-product of mitochondrial metabolism, which is very active for the production of cellular ATP [24]. It is noteworthy that mitochondrial metabolism is known to play a role in susceptibility to ferroptosis through the production of ROS [25,26], which are mainly produced in the mitochondrial respiratory chain during aerobic metabolism [25,27]. Cancer cells are associated with high proliferation and active metabolism. Therefore, they need high levels of energy, resulting in an increased metabolism. This high energy demand leads to excessive ROS generation [28,29,30]. High ROS concentration has been associated with increased aggressiveness and reduced survival in the breast cancer scenario [31]. It has also been reported that PDACs with lower ROS are more resistant to chemotherapy [32], since DNA oxidation and double-strand breaks (DSBs) caused by ROS are known to result in the accumulation of multiple mutations [33]. In cancer cells, the numerous mutations increase the risk of developing resistance to conventional treatments [34].

In addition, triggering ferroptosis has been shown to be effective in overcoming chemotherapy resistance, as demonstrated by Sun et al. with ent-Kaurane diterpenoids suppressing cisplatin resistance [35]. Ferroptosis may also reverse resistance to some immunotherapies, as it has been shown that inhibition of ferroptosis promotes resistance to anti-PD-1/PD-L1 therapy [36]. In the context of overcoming resistance, ferroptosis could be responsible for re-sensitizing cells resistant to radiotherapy. Indeed, in radiotherapy, a large amount of ROS is produced by the up-regulation of ACSL4 and inactivation of ferroptosis scavengers, such as GPX4 [37].

Altering the ROS balance is a way to induce cell death by ferroptosis [22], which would be an effective way to kill cancer cells. Increasing intracellular ROS levels to treat PDAC is an advantage over conventional treatments as it confers chemosensitivity to cancer cells [38,39]. Hence, promoting an imbalance between iron-dependent ROS and cellular detoxification mechanisms subsequently leads to cell death by ferroptosis [23]. To disrupt the ROS balance in the cell and to cause toxicity, one possible approach would be to inhibit the GSH-GPX detoxification system. The loss of GSH would result in the loss of cellular homeostasis and ultimately cellular dysfunction causing cell death by ferroptosis (Figure 1) [40,41].

Given its therapeutic potential, here we review the possibilities of ferroptosis as a therapeutic target in PDAC due to the synergistic effect it has in combination with conventional chemotherapy.

2. Reactive Oxygen Species Balance in PDAC

Oxygen is an essential component of life. But it can be harmful when it causes oxidative stress. Oxidative stress is a phenomenon characterized by an imbalance between the production and detoxification of ROS [42]. These reactive species contain unpaired electrons, which makes them highly reactive oxygen free radicals. Examples of these species are superoxide (O₂⁻) and hydroxyl (OH⁻) which can be transformed into the more stable hydrogen peroxide H₂O₂ [43]. ROS in the cell can act as trigger molecules for cell death, leading to ferroptosis [22].

2.1. Generators of ROS

ROS are continuously generated during aerobic oxygen metabolism. With approximately 80% oxygen consumption, mitochondria are the major contributor to ROS production [44]. The mitochondria are the organelle responsible for producing ATP by oxidation of lipids, glucose and amino acids. In the tricarboxylic acid cycle, an electron from these molecules is donated to the electron transport chain resulting in the oxidation of O₂ to O₂⁻ [45]. More specifically, O₂⁻ is produced at several sites in the mitochondria, including complex I (sites IQ and IF) and complex III (site IIIQ). In the mitochondrial matrix, the O₂⁻ is then converted to H₂O₂ by manganese superoxide dismutase (Mn-SOD). In this manner, H₂O₂ can be converted in OH⁻ via the Fenton reaction [25,46,47]. The Fenton reaction is another source of ROS. This catalytic reaction ends up with ferroptosis, and is dependent on ROS and ferrous ions (Fe²⁺), producing ferric ions (Fe³⁺) [48] (Figure 2A).

Additionally, ROS generated by the nicotinamide adenine dinucleotide phosphate oxidases (NADPH) family have been reported to be implicated in PDAC growth and survival (Figure 2B) [49]. These NOX-derived ROS have been reported to transmit cell survival signals via the AKT-ASK1 pathway and also by inhibiting JAK2 dephosphorylation by tyrosine phosphatases [50,51]. Within this family, there are seven members: NOX1, NOX2, NOX3, NOX4, NOX5, dual oxidase 1 (DUOX1) and DUOX2 [52]. NOX enzymes can transfer electrons throughout the membranes to produce O₂⁻, which will be converted to H₂O₂ [53]. Furthermore, activating NOX can increase intracellular ROS through the interaction with Toll-like receptors, which eventually leads to the activation of the redox-sensitive nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) and NRF2, which is a master regulator of the antioxidant response by controlling the expression of components from GSH antioxidant system (Figure 2B) [54,55]. More specifically, NOX4 is overexpressed in PDAC [56], and has been identified as a potential therapeutic target as it can generate high levels of ROS and also trigger several signaling pathways related to colorectal cancer progression [57]. This NOX-mediated ROS production has been also related to the progression of PDAC at the mRNA level [57,58].

2.2. Scavengers of ROS

From the aforementioned, high intracellular ROS levels can lead to cell death by ferroptosis. However, there are cellular control systems mainly made up of antioxidant enzymes, such as Mn-SOD, catalase (CAT), GPX and thioredoxin (TXN), and other non-enzymatic antioxidants, including GSH, ascorbic acid and tocopherol (Figure 3) [59,60,61].

Physiologically, GSH can detoxify a cancer cell in two ways: directly by interacting with ROS, or indirectly together with GPX. In the latter, GSH acts as a co-substrate of GPX in order to reduce hydrogen peroxide (H₂O₂) and lipid peroxide (Lipid-OOH) into water and lipid hydroxyl (Lipid-OH), respectively [62,63]. GPXs have several isoforms, of which GPX4 is known to be a central regulator of ferroptosis [23]. It has been shown that inhibition of GPX4 signaling through thiostrepton (TST) induces ferroptosis in PDAC cells (Figure 3). Likewise, RAS-selective lethal 3 (RSL3), another GPX4 inhibitor, reduced proliferation in several PDAC-derived cell lines (Figure 3) [64]. Along the same line, ML-162 acts as an inhibitor of GPX4 and induces ferroptosis in gastric cell lines (Figure 3) [65]. Similarly, erastin acts as ferroptosis inducer through the inhibition of the glutamate/cystine antiporter of system Xc⁻ and consequently suppresses the GSH synthesis [66]. These results open the door to new approaches with GPX4 inhibition as a target to increase therapeutic efficacy in combination therapies. Within mitochondrial detoxification systems, H₂O₂ is converted to oxygen and water by peroxidases like CAT in the cytoplasm (Figure 3) [67]. The overexpressed SOD2 system, in synergy with PPAR, inhibits mitochondrial ROS-mediated apoptosis in PDAC cell lines, which promotes PDAC proliferation [68].

2.3. ROS Balance

From the aforementioned research, ferroptosis is a result of missing or insufficient antioxidant defense systems, such as GPX4 and a high ROS intracellular level leading to cell death mediated by membrane lipid peroxidation (LPO) [23,69]. In particular, ferroptosis consists of iron-mediated peroxidation of polyunsaturated fatty acids (PUFAs) (Figure 4). Thus, PUFA production is mainly mediated by two enzymes—acyl-coenzyme A (acyl-CoA) synthetase long-chain family member 4 (ACSL4) and lysophosphatidylcholine acyltransferase 3 (LPCAT3) in the endoplasmic reticulum (ER)—which, in the end, causes LPO mediated by the lipoxygenase (ALOX) [70]. In fact, LPO is a process that occurs in normal cells [71], but when the GSH-GPX4 system is depleted, lipid peroxides can accumulate in cells [22,71] leading to cell membrane rupture, resulting in ferroptotic cell death. Contrary to PUFAs, monounsaturated fatty acids (MUFAs) cannot be peroxidized due to a lack of bis-allylic moieties (Figure 4) [72]. These MUFAs are synthesized by acyl-CoA synthetase long-chain family member 3 (ACSL3) or stearoyl-CoA desaturase (SCD/SCD1). Interestingly, SCD1 is overexpressed in PDAC and correlates with aggressive phenotype by increased tumor size, poor tumor differentiation and short overall survival [73]. Moreover, SCD1 together with MUFAs can compete functionally to inhibit PUFA-related ferroptosis (Figure 4) [72,74].

Considering the above, altering the ROS balance may be a key therapeutic target by inhibiting detoxification systems such as GSH-GPX4, which will thereby eliminate PDAC cells by ferroptosis.

3. ROS Exhibit Specific Biological Functions According to Different Molecular Subtypes of PDAC

In recent years, several cooperative networks, such as the International Cancer Genome Consortium and The Cancer Genome Atlas (TCGA) have been able to distinguish different types of tumors by molecular differences [75,76]. With this knowledge, it is possible to stratify patients according to their differential molecular profile and offer them a specific treatment option to improve their prognosis [77]. Here, we provide an integrated phenotype on the effect of ferroptosis by ROS according to different PDAC molecular subtypes. The rationale to set different molecular subtypes of PDAC is based on the need to stratify patients to perform personalized medicine.

To enhance therapeutic opportunities in PDAC, a molecular taxonomic classification was established to take advantage of the molecular subtypes of pancreatic cancer [9,78].

As mentioned above, PDAC harbors a variety of genetic mutations that lead to KRAS activation as well as the loss of TP53, SMAD4 and CDKN2A [6,7,79]. In addition to these major alterations, there are other molecular mechanisms playing a role in the deregulation of cellular processes: DNA damage repair, TGF-β signaling or cell cycle regulation [78]. A better understanding of gene signaling networks may open the door to cluster PDACs with the goal of developing better therapies.

Bailey and colleagues identified four main molecular subtypes with a whole transcriptomic profile obtained by RNA-seq analysis of 266 primary PDAC samples. These subtypes were squamous (quasi-mesenchymal), pancreatic progenitor (classical), immunogenic and aberrantly differentiated endocrine-exocrine (ADEX, exocrine-like) [78]. Subsequently, Collisson et al. proposed a new stratification based on three different subtypes: quasi-mesenchymal, which is very similar to the squamous molecular subtype proposed by Bailey; the classical subtype equivalent to the previous progenitor subtype; and the exocrine-like subtype previously reported as ADEX [9]. The integration between molecular profiling, histopathology and their microenvironment has been proposed by our group. This integration can significantly help in observing ROS sensitivity in different subtypes of PDACs and could allow us to identify which ones could be more susceptible to cell death by ferroptosis [80].

3.1. The Squamous Molecular Subtype and ROS

The squamous subtype is characterized by a marked mesenchymal phenotype, conferred by the expression of PDX1, HNF1B and GATA6 (Figure 5A). This subtype is related to the worst prognosis due to its capacity to drive epithelial-to-mesenchymal transition (EMT), and therefore, metastases [9,81]. Moreover, the squamous subtype is enriched by TP53 mutations, and presents activation of the TP63ΔN associated network (Figure 5A). TP63ΔN underlies the development of an EMT-like program and maintains the core regulatory network responsible for chromatin accessibility, epigenetic modifications and gene expression patterns (Figure 5A) [9,82]. Normally, P53 can confer antioxidant properties to the cells, providing antitumoral protective functions [83,84]. More specifically, the Tumor Protein 53-Induced Nuclear Protein 1 (TP53INP1), a target of P53, plays a key role in antioxidant defense by participating in the elimination of ROS-producing altered mitochondria [85,86]. Moreover, the functions of the key antioxidant regulator NRF2 can be attenuated by P53 mutant proteins (Figure 5A) [87,88,89].

3.2. The Progenitor Molecular Subtype and ROS

The pancreatic progenitor subtype was equivalent to the classical subtype and featured the epithelial-like phenotype. It is characterized by high expression levels of epithelial and adhesion-associated genes, such as CDH1/E-cadherin [9,78]. This subtype has molecular features of KRAS^mut-dependent PDAC [90]. In addition, FOXA2/3, PDX2, MNX1 and GATA6 are highly expressed in the pancreatic progenitor subtype contributing to early pancreatic development (Figure 5B) [9]. In fact, ROS are critical in the KRAS-driven PDAC [91]. It has been shown that O₂⁻ is a pro-survival factor in PDAC. Consequently, oncogenic KRAS can increase ROS by mitochondrial dysfunction and alteration of NADPH oxidase activities (Figure 5B) [92]. Thus, the mitochondrial ROS can drive essential signaling routes, such as ERK1/2 from the MAPK signaling pathway by upregulation of epidermal growth factor receptor (EGFR) and activation of NF-κB, both of which are implicated in PDAC progression (Figure 5B) [91,93,94]. In this regard, to counteract the high ROS levels due to cancer progression, oncogenic KRAS can up-regulate the antioxidant defense systems. This can occur through NADPH generation by malic enzyme 1 (ME1) and isocitrate dehydrogenase 1 (IDH1), or by contrast through NRF2 activation (Figure 5B) [95,96].

3.3. The Aberrantly Differentiated Endocrine-Exocrine (ADEX, Exocrine-Like) Subtype and ROS

ADEX tumor subtype stands out for exhibiting transcriptional programs characteristic of a more terminally differentiated normal pancreas. This subtype can exhibit both an exocrine or an endocrine transcriptional profile [9]. On the one hand, the main networks identified in ADEX involve the transcription factors NR5A2, MIST1 and RBPJL, whose main role is to drive acinar differentiation, pancreatitis and regeneration (Figure 5C) [78,97,98]. On the other hand, INS, NEUROD1, NKX2-2 and MAFA are associated with endocrine differentiation and onset diabetes (Figure 5C) [78]. This genetic profile has been linked to KRAS activation [9,78]. Concerning ROS generation in this subtype, the serine/threonine kinase Protein Kinase D1 (PKD1) is a major contributor to mitochondrial ROS (mtROS) generation [99]. Indeed, when activated, PKD1 can increase PDAC cancer cells’ survival through the inactivation of c-Jun N-terminal kinases (JNK) 1/2 and P38 signaling (Figure 5C) [100].

3.4. The Immunogenic Subtype and ROS

The immunogenic subtype has a molecular profile very similar to the pancreatic progenitor subtype. This profile can be differentiated by the pattern of the immune infiltration resident within the TME, and more specifically, in the stroma. This stroma is comprised of extracellular matrix proteins, tumor-associated vasculature, fibroblasts and immune cells, which engender a poor prognosis in PDAC and ultimately hinder drug delivery [101]. From the foregoing, this subtype is associated with a decrease in tumor-like cells, and consequently, immune cells play a major role in this tumor subtype [9]. Thus, in tumors where there is a significant infiltration of immune cells, such as M1-like macrophages, there is a higher survival rate due to greater activation of resident memory cells (Figure 5D) [102]. Nevertheless, this immunogenic PDAC is associated with the classical subtype (previously described by Collisson et al.), which was, in turn, governed by the oncogenic phenotype of KRAS and the oxidative stress it caused conferring a pro-survival factor to PDAC cells [9,92,95,96]. The oncogenic phenotype of activated KRAS is followed by loss of phosphatase and tensin homolog (PTEN), which is a tumor suppressor gene that inhibits the PI3K/AKT signaling pathway and has a prevalence of 60% in PDAC (Figure 5D) [103].

Considered together, these molecular scenarios bring new rationales for different possibilities for inducing cell death in PDAC. Thus, recapping the aforementioned, ferroptosis is a type of cell death that has a lot of potential [22,104]. If we can take into account the molecular subtypes of PDAC, we can enhance its effectiveness, and provide the best treatment for each patient to solve a personalized medicine challenge. Following this assumption, all pancreatic progenitor, ADEX and immunogenic patients could be treated in order to increase intracellular ROS and decrease the levels of antioxidant systems, as previously described with oncogenic KRAS colorectal cancer (CRC) models treated with β-elemene (Pterodon emarginatus) and Cetuximab [105]. Also, in these three PDAC subtypes, it could be interesting to target the NRF2 signaling pathway. Cetuximab is reported to boost RSL3-induced ferroptosis by inhibiting the NRF2 pathway in KRAS-mutated CRC cells [106]. Regarding squamous PDAC, it presents a mutated TP53 genetic background, which offers a divergent model of ROS production and hence ferroptosis [107]. On the one hand, P53 can decrease intracellular levels of ROS and regulate metabolic intermediates, such as TIGAR and GLS2, that decrease cellular levels of ROS [108,109]. On the other hand, P53 has been found to play a major role in inducing ferroptosis by transcriptional repression of SLC7A11, impairing cysteine import and promoting ferroptosis initiation [107,110]. Therefore, new approaches to studying the role of P53 in ferroptosis are needed.

In that sense, ferroptosis is the final process to which all of these pathways would lead. Similarly, the activation of caspases by macromolecular processes results in the activation of procaspases and the proteolytic process that will lead to cell death by apoptosis [111]. Meanwhile, ferroptosis is a caspase-independent cell death that is produced by PUFA oxidation via intracellular high ROS levels [112]. Lipoxygenases (LOX) activity can catalyze PUFA-containing phospholipids and generate a pool of pro-ferroptotic peroxidized lipids [113]. Subsequently, iron is an essential component of the Fenton reaction to produce an intracellular ROS [114]. Free iron in the cell is essential for ferroptosis. However, iron is not required to trigger apoptosis. Iron chelators can act as control systems for the ferroptosis [115,116]. In this regard, GPX4 may act by preventing the toxicity produced by peroxidized lipids while maintaining the integrity of the lipid bilayer [117].

Given this overview of PDAC molecular subtypes and their involvement in the ferroptosis process, we will now analyze the interaction between ROS and chemotherapy treatments commonly used in routine clinical practice.

4. Reactive Oxygen Species and Commonly Used Chemotherapy in PDAC

From the aforementioned, PDAC can only be resected in a minority of cases, and the prognosis for survival after surgery is about one year [118,119,120]. At this point, combined chemotherapy is the most used option to treat PDAC patients after resection and in unresectable cases to improve disease-free survival and overall survival [121]. ROS production is a shared consequence among chemotherapies due to their involvement in triggering cell death. Therefore, combinatorial therapy based on ROS generation to increase toxicity and susceptibility to other adjuvant therapies would be a potential therapeutic approach. In this section, the modulation of ROS by the main chemotherapeutics against PDAC will be discussed.

Gemcitabine monotherapy has been traditionally the cornerstone of chemotherapy in PDAC. Now, it is used in frail patients. It is known that gemcitabine induces the accumulation of ROS during treatment, which is a new cytotoxic effect that has come under the spotlight in recent years [122]. Some studies have shown mechanisms by which gemcitabine can cause ROS accumulation through NF-kB activation [123], and thus have a possible role in favoring ferroptosis. It has also been reported that gemcitabine can induce GSH synthesis by activation of NRF2. Thus, favoring gemcitabine resistance in the end (Figure 6) [124].

While less recommended, capecitabine monotherapy is also useful in selected patients and in combination with gemcitabine [10]. A study using cardiomyocytes reported that capecitabine could cause lipid peroxidation and oxidative stress [125]. Thus, it causes ferroptosis, thereby increasing its cytotoxic effect.

Within polychemotherapies, FOLFIRINOX is used in the first line of treatment for PDAC [10]. This chemotherapeutic regimen contains 5-FU, which has been shown to elevate ROS levels and trigger mitochondrial dysfunction by up-regulating BAX/BCL-2. In a study, it was found that suppressing the generation of ROS abolished the cell growth inhibition of 5-FU [126]. Irinotecan has been reported to increase intracellular ROS levels and cause cell death by the activation of JNK and P38 MAPK pathways (Figure 6) [127]. Oxaliplatin can also increase intracellular ROS and cause apoptosis in a dose-dependent manner in PANC-1 and MIA PaCa-2 [128]. In combination, these drugs that make up FOLFIRINOX can have a synergistic cytotoxic effect in such a way as to generate elevated oxidative stress to ultimately cause ferroptosis.

To follow up with polychemotherapies, a common combination to treat metastatic PDAC is gemcitabine plus albumin-bound paclitaxel [10]. It has been shown that paclitaxel can increase the amount of intracellular ROS and inhibit the antioxidant action of SOD-2 (Figure 6) [129]. The combination of gemcitabine and paclitaxel can be very interesting since increasing intracellular ROS levels and inhibiting antioxidant systems can cause cell death by ferroptosis, enhancing cytotoxicity and improving the efficacy of chemotherapy.

5. Potential Clinical Benefits of Ferroptosis Modulation in PDAC

As previously reported, current cancer treatments have limited clinical efficacy in PDAC patients. An important reason for therapeutic failure is drug resistance, especially when cancer cells are able to avoid apoptosis [130]. In this review, we discuss how ROS and ferroptosis are a potential route to tackle cancer, specifically altering ROS balance to produce cell death through ferroptosis. This could be a chemotherapeutic option per se or enhance the effect of other treatments. In this section, the main approaches to alter ROS and produce ferroptosis in PDAC will be addressed, as well as the possibilities to be set as a new chemotherapeutic regimen alone or used in combination to enhance current adjuvant therapies.

5.1. Targeting Oxidants

It is known that tumor cells produce significant amounts of ROS when they grow and metastasize. Despite the high amount of ROS, tumor cells manage to maintain the redox balance. This ability is due to the maintenance of a high expression of antioxidant systems, which ultimately prevents exceeding the ROS threshold that would lead to cell death by apoptosis or ferroptosis [131,132].

Arsenic trioxide (ATO) is considered an oxidizing agent. It is capable of producing oxidative damage not only by inhibiting antioxidant systems, such as SOD, GSH or GPX, but also through the production of ROS (Figure 7) [133]. Regarding the production of ROS by ATO, it has been shown that its administration can cause overexpression of Caspases 3, 7 and 9 in PDAC cells, which in turn leads to apoptosis [134]. Moreover, ATO has been reported to cause cell cycle arrest at the G1 or G2-M phase as long as RB is hypophosphorylated and CDC25 B/C phosphatases are reduced by the inhibition of CDK2/6 and CDC2-associated kinases [135]. Another property of ATO is that it can restore the correct folding of TP53 proteins more efficiently than other TP53 reactivating molecules [136], which could be an interesting approach in PDAC. ATO is currently approved therapy for high-risk acute promyelocytic leukemia [137]. But its therapeutic potential for PDAC patients does not seem as promising in pre-clinical studies. For instance, phase II study did not show a significant response with a median survival of 3.8 months [138].

Furthermore, vitamin C is among the molecules that have a pro-oxidant effect. Although it has traditionally been identified as an antioxidant, high doses of vitamin C have antitumor effects by generating large amounts of intracellular ROS. This is due to the fact that tumor cells are forced to reduce a large amount of dehydroascorbate (DHA), which is an oxidized form of vitamin C (Figure 7) [139]. Additionally, among the oxidizing molecules, piperlongumine (PL) and artesunate (ART) have been proven to induce an increase in ROS causing cell death. It has been reported that in a dose-dependent manner, PL increases ROS levels intracellularly and inhibits GPX activity by GSH depletion, which ultimately induce ferroptosis (Figure 7) [140]. ART has been shown to induce iron-triggered and ROS-mediated cell death in different PDAC cell lines [141]. Along the same line, it leads to GSH depletion and lipid peroxidation and, finally, triggers ferroptosis. There are some pharmacological agents that use these pathways to induce cell death through oxidative stress, such as imidazole ketone erastin (IKE) and cyst(e)inase [142,143]. In addition, antioxidant inhibitors, such as RSL-3 and ML-162 are used to induce oxidative stress. The mechanism of action of these inhibitors involves the inhibition of GPXs. These inhibitors have been shown to increase lipid peroxidation and cause ferroptosis in PDAC [144] and in head and neck cancer-derived cell lines [65]. In another study carried out in PDAC cell lines, laminarin, a glucan derived from brown algae, has been tested as a possible inducer of cell death. In the study, they found that laminarin could increase ROS levels, trigger apoptosis and inhibit cell proliferation and migration in a dose-dependent manner [145].

5.2. Targeting Antioxidants

In PDAC development, tumor cells produce large amounts of ROS and other free radicals that help tumor cells grow, survive and proliferate [92]. ROS have been linked to the initiation of tumorigenesis and the alteration of cellular processes through their effect on protein function [146]. Hence, an excessive amount of oxidative stress causes the total loss of function of some proteins, which are necessary for the adaptation of metabolic and antioxidant programs involved in the clearance of oxidative stress [147].

Therefore, maintaining the balance of antioxidants is important as there are all types of enzymes or cofactors that are involved in the elimination of intracellular ROS. There are two classes of antioxidants: endogenous and exogenous antioxidants. Among endogenous antioxidants, the main cellular antioxidant system is GSH-dependent in which GSH is used as a cofactor by GSH S-transferases (GSTs) and GSH peroxidases (GPXs) to eliminate ROS. Besides the GSH-GPXs axis, there are networks based on peroxiredoxins (PRDXs) regeneration, which are sulfaredoxin (SRX) and thioredoxin. This enzyme cluster exhibits high catalytic activity toward H₂O₂ [23,148]. Furthermore, the antioxidant systems SOD1 and SOD2 stand out and act at the cytosol and mitochondrial level, respectively. They play a role in the ROS scavenging [60]. It has been shown that the loss of antioxidants, such as GPX1, GPX3 or SOD2, could increase tumor progression in several mouse models [149,150]. In addition, in a mouse model of PDAC, metastasis was decreased by injection of TIGAR, an endogenous antioxidant [151].

Many exogenous antioxidants have been evaluated in in vitro models and clinical trials to test their antitumor efficacy. The rationale for this is based on several studies that have reported that certain antioxidants ingested in the diet can inhibit tumor cell proliferation, and even cause tumor cell apoptosis, particularly in combination with chemotherapy [152]. Several flavonoid compounds, such as genistein, capsaicin and benzyl isothiocyanate, which are derived from plants, have been tested for their ability to induce apoptosis in PDAC cell lines [153]. In addition, studies have been reported with δ-Tocotrienol, a natural form of vitamin E, which acts as an antioxidant. This compound has been shown to inhibit tumor growth and metastasis in PDAC in mice models [154]. Empowering antioxidant systems is an interesting strategy in PDAC to decrease DNA damage caused by oxidative stress and decrease tumor growth potential.

5.3. Combination Approaches

Considering oxidizing agents and antioxidants separately, we have been able to see that certain compounds exhibit antitumor activity on their own. But the most interesting approach would be a combination of oxidants or antioxidants together with chemotherapy schemes. The rationale of these combinations would be to sensitize PDACs to chemotherapies by modulating oxidant and antioxidant compounds since resistance to chemotherapy is still a limiting factor in PDACs.

Among the possible combinations of therapeutic agents, stress-inducing agents stand out. These agents include the combination of etoposide and trigonelline in in vitro and in vivo models of PDAC. Trigonelline is a coffee alkaloid that has been shown to cause lipid oxidation and susceptibility to apoptosis. In combination with the topoisomerase II inhibitor agent, etoposide potentiates apoptosis in PDAC models [155]. Moreover, a study has reported that the diterpenoid libertellenone H (LH) is able to inhibit the antioxidant system Thioredoxin and induce ROS-mediated apoptosis in PDAC cell lines. It has also been reported that this effect could be reversed by the Mn-SOD enzyme [156]. So, an interesting approach would be to combine LH with an inhibitor of the antioxidant Mn-SOD to enhance the oxidative effect that triggers apoptosis.

In line with the combination of oxidizing agents and chemotherapy, a possible combination of oxaliplatin with a mangiferin, a glucosylxanthone, aims to be effective in inducing cell death in PDAC. On the one hand, it has been shown in a study with PDAC cell lines that mangiferin can induce autophagy, mitochondria-triggered apoptosis, cell cycle arrest and the suppression of tumor migration and invasion [157]. On the other hand, in a previous study, it has been shown that the combination of mangiferin and oxaliplatin has a synergistic effect favoring apoptosis and opens the door to the reduction in resistance to chemotherapy in different cancer cell lines [158]. Meanwhile, some widespread flavonoids, such as quercetin can produce P-53-independent ferroptosis in cancer cell lines. Quercetin can increase the amount of intracellular and mitochondrial ROS, as well as increase the production of ACSL4, which ultimately alters the balance towards ferroptosis through lipid peroxidation. Contrary to this, it was observed that in quercetin-treated cells, GPX4 expression was decreased, further altering the balance towards ferroptosis (Figure 7) [159].

This approach could be interesting in PDAC since it is a pathway that induces cell death by ferroptosis and is independent of P53. So, it would be even more interesting to investigate it in the squamous–P53 deficient PDAC. To support combinatorial therapies between oxidative compounds, it has been shown that the combination of cotylenin A (CN-A) and phenethyl isothiocyanate (PEITC) can produce ROS-triggered ferroptosis in PDAC cells. This joint effect of CN-A and PEITC could be reversed with a ROS scavenger (N-acetylcysteine) together to a ferroptosis inhibitor (liproxstatin). Thus, demonstrating the ROS-enhancing effect of this combination of compounds to produce ferroptosis [160]. In line with this, a previous study reported that CN-A showed a synergistic effect on cell death and reduced invasiveness in breast cancer cells [161].

In addition to the approaches mentioned above, there are other ways to modulate ferroptosis. Among these is the regulation of molecules essential in the maintenance of cellular energy balance, such as AMPK. The role of AMPK in ferroptosis resistance was evaluated in ferroptosis-resistant kidney cell lines (ACHN). This cell line, also characterized by high basal AMPK expression, was subjected to treatment with compound C, resulting in ferroptosis sensitization of cells that were resistant when treated with erastin or cisterna detection [162].

6. Conclusions

In conclusion, all these different approaches on how to alter the ROS balance to trigger ferroptosis directly or through the intermediates involved turn out to have great potential in PDAC, a type of tumor with a poor prognosis where current treatments are not fully effective. In this review, the possibilities of modulating ferroptosis in the PDAC have been explored. Numerous ferroptosis activators are currently under development, with a particular focus on GPX4. However, our approach goes far beyond inhibiting GPX4 and proposes different alternatives to cause the increase in ROS that triggers lipid peroxidation and thus ferroptosis. The main idea and future perspectives will focus on therapy based on combinations of oxidizing agents, to increase ROS and limit the negative effects of each oxidant separately. Consequently, considering these combinatorial therapies targeting ROS-dependent ferroptosis, the therapeutic options in the clinic would increase and with them the outcome of PDAC patients.

Footnotes

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

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Figure 1. Mechanism of ferroptosis in tumor cells under physiologic and ferroptotic process. Arrows indicate activation and T bars denote repression.

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Figure 2. Different cellular ROS production. (A) ROS generation in the mitochondria. O2− is produced in sites IQ, IF and IIIQ and converted in H2O2. Then, Fenton reaction takes place to convert H2O2 in OH− and lead to oxidation of Fe2+ to Fe3+. (B) Intracellular ROS production in pancreatic tumor cells by NOX family of proteins and its role in PDAC maintenance. Arrows indicate activation and T bars denote repression.

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Figure 3. Common antioxidants and mechanism of detoxification in cytoplasm of PDAC. Arrows indicate activation and T bars denote inhibition.

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Figure 4. PUFA and MUFA generation, associated factors, and their involvement in ferroptosis. AA: arachidonic acid. OA: Oleic Acid. LA: Linoleic Acid. Arrows indicate activation and T bars denote repression. Blue arrows denote higher reduction and red arrows denote higher increase.

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Figure 5. ROS involvement according to different molecular subtypes of PDAC. (A) ROS modulation in PDAC squamous molecular subtype and the crucial role of TP53 as an antioxidant. (B) ROS modulation in progenitor molecular subtype where KRASmut plays a crucial role. (C) Aberrantly differentiated endocrine–exocrine (ADEX, exocrine-like) and factor involved in ROS generation. (D) ROS generation and molecular features of the immunogenic molecular subtype of PDAC. Arrows indicate activation and T bars denote inhibition.

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Figure 6. ROS modulation by most used chemotherapies against PDAC. Nab-Paclitaxel: nano-albumin bound paclitaxel.

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Figure 7. Molecular strategies to target oxidants as a new approach against PDAC.

References

1. Siegel, R.L.; Miller, K.D.; Wagle, N.S.; Jemal, A. Cancer Statistics, 2023. CA Cancer J. Clin.; 2023; 73, pp. 17-48. [DOI: https://dx.doi.org/10.3322/caac.21763] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36633525]

2. Helaly, M.; Sriwi, D.; Alkholaidi, W.S.; Almamlouk, R.; Elshaer, A.; Allaboon, R.M.; Hassan, L.H.; Khalifa, H.; Al-Alem, I. Retrograde Pancreatic Duct Stent Migration into the Biliary Tract Presenting as a Rare Early Complication of Pancreaticoduodenectomy (Whipple Procedure). Am. J. Case Rep.; 2019; 20, pp. 1864-1868. [DOI: https://dx.doi.org/10.12659/AJCR.917297] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31831724]

3. Arnold, M.; Abnet, C.C.; Neale, R.E.; Vignat, J.; Giovannucci, E.L.; McGlynn, K.A.; Bray, F. Global Burden of 5 Major Types of Gastrointestinal Cancer. Gastroenterology; 2020; 159, pp. 335-349.e15. [DOI: https://dx.doi.org/10.1053/j.gastro.2020.02.068] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32247694]

4. Huang, L.; Jansen, L.; Balavarca, Y.; Babaei, M.; van der Geest, L.; Lemmens, V.; Van Eycken, L.; De Schutter, H.; Johannesen, T.B.; Primic-Žakelj, M. et al. Stratified Survival of Resected and Overall Pancreatic Cancer Patients in Europe and the USA in the Early Twenty-First Century: A Large, International Population-Based Study. BMC Med.; 2018; 16, 125. [DOI: https://dx.doi.org/10.1186/s12916-018-1120-9]

5. Arnold, M.; Rutherford, M.J.; Bardot, A.; Ferlay, J.; Andersson, T.M.-L.; Myklebust, T.Å.; Tervonen, H.; Thursfield, V.; Ransom, D.; Shack, L. et al. Progress in Cancer Survival, Mortality, and Incidence in Seven High-Income Countries 1995-2014 (ICBP SURVMARK-2): A Population-Based Study. Lancet Oncol.; 2019; 20, pp. 1493-1505. [DOI: https://dx.doi.org/10.1016/S1470-2045(19)30456-5]

6. Aguirre, A.J.; Nowak, J.A.; Camarda, N.D.; Moffitt, R.A.; Ghazani, A.A.; Hazar-Rethinam, M.; Raghavan, S.; Kim, J.; Brais, L.K.; Ragon, D. et al. Real-Time Genomic Characterization of Advanced Pancreatic Cancer to Enable Precision Medicine. Cancer Discov.; 2018; 8, pp. 1096-1111. [DOI: https://dx.doi.org/10.1158/2159-8290.CD-18-0275]

7. Qian, Z.R.; Rubinson, D.A.; Nowak, J.A.; Morales-Oyarvide, V.; Dunne, R.F.; Kozak, M.M.; Welch, M.W.; Brais, L.K.; Da Silva, A.; Li, T. et al. Association of Alterations in Main Driver Genes With Outcomes of Patients With Resected Pancreatic Ductal Adenocarcinoma. JAMA Oncol.; 2018; 4, e173420. [DOI: https://dx.doi.org/10.1001/jamaoncol.2017.3420]

8. Park, W.; Chen, J.; Chou, J.F.; Varghese, A.M.; Yu, K.H.; Wong, W.; Capanu, M.; Balachandran, V.; McIntyre, C.A.; El Dika, I. et al. Genomic Methods Identify Homologous Recombination Deficiency in Pancreas Adenocarcinoma and Optimize Treatment Selection. Clin. Cancer Res.; 2020; 26, pp. 3239-3247. [DOI: https://dx.doi.org/10.1158/1078-0432.CCR-20-0418]

9. Collisson, E.A.; Bailey, P.; Chang, D.K.; Biankin, A.V. Molecular Subtypes of Pancreatic Cancer. Nat. Rev. Gastroenterol. Hepatol.; 2019; 16, pp. 207-220. [DOI: https://dx.doi.org/10.1038/s41575-019-0109-y]

10. Guidelines Detail. Available online: https://www.nccn.org/guidelines/guidelines-detail (accessed on 22 March 2023).

11. Müller, P.C.; Frey, M.C.; Ruzza, C.M.; Nickel, F.; Jost, C.; Gwerder, C.; Hackert, T.; Z’graggen, K.; Kessler, U. Neoadjuvant Chemotherapy in Pancreatic Cancer: An Appraisal of the Current High-Level Evidence. Pharmacology; 2021; 106, pp. 143-153. [DOI: https://dx.doi.org/10.1159/000510343]

12. StatBite. U.S. Pancreatic Cancer Rates. J. Natl. Cancer Inst.; 2010; 102, 1822. [DOI: https://dx.doi.org/10.1093/jnci/djq517] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/21139097]

13. Pusceddu, S.; Ghidini, M.; Torchio, M.; Corti, F.; Tomasello, G.; Niger, M.; Prinzi, N.; Nichetti, F.; Coinu, A.; Di Bartolomeo, M. et al. Comparative Effectiveness of Gemcitabine plus Nab-Paclitaxel and FOLFIRINOX in the First-Line Setting of Metastatic Pancreatic Cancer: A Systematic Review and Meta-Analysis. Cancers; 2019; 11, 484. [DOI: https://dx.doi.org/10.3390/cancers11040484] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30959763]

14. Wainberg, Z.A.; Melisi, D.; Macarulla, T.; Pazo-Cid, R.; Chandana, S.R.; Fouchardiere, C.D.L.; Dean, A.P.; Kiss, I.; Lee, W.; Goetze, T.O. et al. NAPOLI-3: A Randomized, Open-Label Phase 3 Study of Liposomal Irinotecan + 5-Fluorouracil/Leucovorin + Oxaliplatin (NALIRIFOX) versus Nab-Paclitaxel + Gemcitabine in Treatment-Naïve Patients with Metastatic Pancreatic Ductal Adenocarcinoma (mPDAC). J. Clin. Oncol.; 2023; 41, LBA661. [DOI: https://dx.doi.org/10.1200/JCO.2023.41.4_suppl.LBA661]

15. Pylayeva-Gupta, Y.; Lee, K.E.; Hajdu, C.H.; Miller, G.; Bar-Sagi, D. Oncogenic Kras-Induced GM-CSF Production Promotes the Development of Pancreatic Neoplasia. Cancer Cell; 2012; 21, pp. 836-847. [DOI: https://dx.doi.org/10.1016/j.ccr.2012.04.024]

16. Olivares, O.; Mayers, J.R.; Gouirand, V.; Torrence, M.E.; Gicquel, T.; Borge, L.; Lac, S.; Roques, J.; Lavaut, M.-N.; Berthezène, P. et al. Collagen-Derived Proline Promotes Pancreatic Ductal Adenocarcinoma Cell Survival under Nutrient Limited Conditions. Nat. Commun.; 2017; 8, 16031. [DOI: https://dx.doi.org/10.1038/ncomms16031]

17. Guillaumond, F.; Bidaut, G.; Ouaissi, M.; Servais, S.; Gouirand, V.; Olivares, O.; Lac, S.; Borge, L.; Roques, J.; Gayet, O. et al. Cholesterol Uptake Disruption, in Association with Chemotherapy, Is a Promising Combined Metabolic Therapy for Pancreatic Adenocarcinoma. Proc. Natl. Acad. Sci. USA; 2015; 112, pp. 2473-2478. [DOI: https://dx.doi.org/10.1073/pnas.1421601112]

18. Beatty, G.L.; Torigian, D.A.; Chiorean, E.G.; Saboury, B.; Brothers, A.; Alavi, A.; Troxel, A.B.; Sun, W.; Teitelbaum, U.R.; Vonderheide, R.H. et al. A Phase I Study of an Agonist CD40 Monoclonal Antibody (CP-870,893) in Combination with Gemcitabine in Patients with Advanced Pancreatic Ductal Adenocarcinoma. Clin. Cancer Res.; 2013; 19, pp. 6286-6295. [DOI: https://dx.doi.org/10.1158/1078-0432.CCR-13-1320]

19. Beatty, G.L.; Chiorean, E.G.; Fishman, M.P.; Saboury, B.; Teitelbaum, U.R.; Sun, W.; Huhn, R.D.; Song, W.; Li, D.; Sharp, L.L. et al. CD40 Agonists Alter Tumor Stroma and Show Efficacy against Pancreatic Carcinoma in Mice and Humans. Science; 2011; 331, pp. 1612-1616. [DOI: https://dx.doi.org/10.1126/science.1198443]

20. Byrne, K.T.; Betts, C.B.; Mick, R.; Sivagnanam, S.; Bajor, D.L.; Laheru, D.A.; Chiorean, E.G.; O’Hara, M.H.; Liudahl, S.M.; Newcomb, C. et al. Neoadjuvant Selicrelumab, an Agonist CD40 Antibody, Induces Changes in the Tumor Microenvironment in Patients with Resectable Pancreatic Cancer. Clin. Cancer Res.; 2021; 27, pp. 4574-4586. [DOI: https://dx.doi.org/10.1158/1078-0432.CCR-21-1047]

21. Lutz, E.; Yeo, C.J.; Lillemoe, K.D.; Biedrzycki, B.; Kobrin, B.; Herman, J.; Sugar, E.; Piantadosi, S.; Cameron, J.L.; Solt, S. et al. A Lethally Irradiated Allogeneic Granulocyte-Macrophage Colony Stimulating Factor-Secreting Tumor Vaccine for Pancreatic Adenocarcinoma. A Phase II Trial of Safety, Efficacy, and Immune Activation. Ann. Surg.; 2011; 253, pp. 328-335. [DOI: https://dx.doi.org/10.1097/SLA.0b013e3181fd271c]

22. Dixon, S.J.; Lemberg, K.M.; Lamprecht, M.R.; Skouta, R.; Zaitsev, E.M.; Gleason, C.E.; Patel, D.N.; Bauer, A.J.; Cantley, A.M.; Yang, W.S. et al. Ferroptosis: An Iron-Dependent Form of Nonapoptotic Cell Death. Cell; 2012; 149, pp. 1060-1072. [DOI: https://dx.doi.org/10.1016/j.cell.2012.03.042] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/22632970]

23. Yang, W.S.; SriRamaratnam, R.; Welsch, M.E.; Shimada, K.; Skouta, R.; Viswanathan, V.S.; Cheah, J.H.; Clemons, P.A.; Shamji, A.F.; Clish, C.B. et al. Regulation of Ferroptotic Cancer Cell Death by GPX4. Cell; 2014; 156, pp. 317-331. [DOI: https://dx.doi.org/10.1016/j.cell.2013.12.010] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/24439385]

24. Kausar, S.; Wang, F.; Cui, H. The Role of Mitochondria in Reactive Oxygen Species Generation and Its Implications for Neurodegenerative Diseases. Cells; 2018; 7, 274. [DOI: https://dx.doi.org/10.3390/cells7120274] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30563029]

25. Murphy, M.P. How Mitochondria Produce Reactive Oxygen Species. Biochem. J.; 2009; 417, pp. 1-13. [DOI: https://dx.doi.org/10.1042/BJ20081386] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/19061483]

26. Zheng, J.; Conrad, M. The Metabolic Underpinnings of Ferroptosis. Cell Metab.; 2020; 32, pp. 920-937. [DOI: https://dx.doi.org/10.1016/j.cmet.2020.10.011] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33217331]

27. Munro, D.; Treberg, J.R. A Radical Shift in Perspective: Mitochondria as Regulators of Reactive Oxygen Species. J. Exp. Biol.; 2017; 220, pp. 1170-1180. [DOI: https://dx.doi.org/10.1242/jeb.132142]

28. Pavlova, N.N.; Zhu, J.; Thompson, C.B. The Hallmarks of Cancer Metabolism: Still Emerging. Cell Metab.; 2022; 34, pp. 355-377. [DOI: https://dx.doi.org/10.1016/j.cmet.2022.01.007]

29. Camelo, F.; Le, A. The Intricate Metabolism of Pancreatic Cancers. The Heterogeneity of Cancer Metabolism; Le, A. Advances in Experimental Medicine and Biology Springer International Publishing: Cham, Switzerland, 2021; pp. 77-88. ISBN 978-3-030-65768-0

30. Park, J.K.; Coffey, N.J.; Limoges, A.; Le, A. The Heterogeneity of Lipid Metabolism in Cancer. The Heterogeneity of Cancer Metabolism; Le, A. Advances in Experimental Medicine and Biology Springer International Publishing: Cham, Switzerland, 2021; pp. 39-56. ISBN 978-3-030-65768-0

31. Oshi, M.; Gandhi, S.; Yan, L.; Tokumaru, Y.; Wu, R.; Yamada, A.; Matsuyama, R.; Endo, I.; Takabe, K. Abundance of Reactive Oxygen Species (ROS) Is Associated with Tumor Aggressiveness, Immune Response, and Worse Survival in Breast Cancer. Breast Cancer Res. Treat.; 2022; 194, pp. 231-241. [DOI: https://dx.doi.org/10.1007/s10549-022-06633-0]

32. Donadelli, M.; Dando, I.; Zaniboni, T.; Costanzo, C.; Dalla Pozza, E.; Scupoli, M.T.; Scarpa, A.; Zappavigna, S.; Marra, M.; Abbruzzese, A. et al. Gemcitabine/Cannabinoid Combination Triggers Autophagy in Pancreatic Cancer Cells through a ROS-Mediated Mechanism. Cell Death Dis.; 2011; 2, e152. [DOI: https://dx.doi.org/10.1038/cddis.2011.36]

33. Stanicka, J.; Russell, E.G.; Woolley, J.F.; Cotter, T.G. NADPH Oxidase-Generated Hydrogen Peroxide Induces DNA Damage in Mutant FLT3-Expressing Leukemia Cells*. J. Biol. Chem.; 2015; 290, pp. 9348-9361. [DOI: https://dx.doi.org/10.1074/jbc.M113.510495]

34. Pettitt, S.J.; Krastev, D.B.; Brandsma, I.; Dréan, A.; Song, F.; Aleksandrov, R.; Harrell, M.I.; Menon, M.; Brough, R.; Campbell, J. et al. Genome-Wide and High-Density CRISPR-Cas9 Screens Identify Point Mutations in PARP1 Causing PARP Inhibitor Resistance. Nat. Commun.; 2018; 9, 1849. [DOI: https://dx.doi.org/10.1038/s41467-018-03917-2] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/29748565]

35. Sun, Y.; Qiao, Y.; Liu, Y.; Zhou, J.; Wang, X.; Zheng, H.; Xu, Z.; Zhang, J.; Zhou, Y.; Qian, L. et al. Ent-Kaurane Diterpenoids Induce Apoptosis and Ferroptosis through Targeting Redox Resetting to Overcome Cisplatin Resistance. Redox Biol.; 2021; 43, 101977. [DOI: https://dx.doi.org/10.1016/j.redox.2021.101977] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33905957]

36. Jiang, Z.; Lim, S.-O.; Yan, M.; Hsu, J.L.; Yao, J.; Wei, Y.; Chang, S.-S.; Yamaguchi, H.; Lee, H.-H.; Ke, B. et al. TYRO3 Induces Anti–PD-1/PD-L1 Therapy Resistance by Limiting Innate Immunity and Tumoral Ferroptosis. J. Clin. Investig.; 2021; 131, e139434. [DOI: https://dx.doi.org/10.1172/JCI139434] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33855973]

37. Zhao, L.; Zhou, X.; Xie, F.; Zhang, L.; Yan, H.; Huang, J.; Zhang, C.; Zhou, F.; Chen, J.; Zhang, L. Ferroptosis in Cancer and Cancer Immunotherapy. Cancer Commun.; 2022; 42, pp. 88-116. [DOI: https://dx.doi.org/10.1002/cac2.12250]

38. Fiorini, C.; Cordani, M.; Gotte, G.; Picone, D.; Donadelli, M. Onconase Induces Autophagy Sensitizing Pancreatic Cancer Cells to Gemcitabine and Activates Akt/mTOR Pathway in a ROS-Dependent Manner. Biochim. Biophys. Acta; 2015; 1853, pp. 549-560. [DOI: https://dx.doi.org/10.1016/j.bbamcr.2014.12.016]

39. Kong, R.; Jia, G.; Cheng, Z.; Wang, Y.; Mu, M.; Wang, S.; Pan, S.; Gao, Y.; Jiang, H.; Dong, D. et al. Dihydroartemisinin Enhances Apo2L/TRAIL-Mediated Apoptosis in Pancreatic Cancer Cells via ROS-Mediated up-Regulation of Death Receptor 5. PLoS ONE; 2012; 7, e37222. [DOI: https://dx.doi.org/10.1371/annotation/f7203563-87dc-4d11-a1b7-958f81cf743a]

40. Jagust, P.; Alcalá, S.; Sainz Jr, B.; Heeschen, C.; Sancho, P. Glutathione Metabolism Is Essential for Self-Renewal and Chemoresistance of Pancreatic Cancer Stem Cells. World J. Stem Cells; 2020; 12, pp. 1410-1428. [DOI: https://dx.doi.org/10.4252/wjsc.v12.i11.1410]

41. Lee, M.; Cho, T.; Jantaratnotai, N.; Wang, Y.T.; McGeer, E.; McGeer, P.L. Depletion of GSH in Glial Cells Induces Neurotoxicity: Relevance to Aging and Degenerative Neurological Diseases. FASEB J.; 2010; 24, pp. 2533-2545. [DOI: https://dx.doi.org/10.1096/fj.09-149997]

42. Commoner, B.; Townsend, J.; Pake, G.E. Free Radicals in Biological Materials. Nature; 1954; 174, pp. 689-691. [DOI: https://dx.doi.org/10.1038/174689a0]

43. Dickinson, B.C.; Chang, C.J. Chemistry and Biology of Reactive Oxygen Species in Signaling or Stress Responses. Nat. Chem. Biol.; 2011; 7, pp. 504-511. [DOI: https://dx.doi.org/10.1038/nchembio.607]

44. Han, D.; Williams, E.; Cadenas, E. Mitochondrial Respiratory Chain-Dependent Generation of Superoxide Anion and Its Release into the Intermembrane Space. Biochem. J.; 2001; 353, pp. 411-416. [DOI: https://dx.doi.org/10.1042/bj3530411] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/11139407]

45. Quinlan, C.L.; Treberg, J.R.; Perevoshchikova, I.V.; Orr, A.L.; Brand, M.D. Native Rates of Superoxide Production from Multiple Sites in Isolated Mitochondria Measured Using Endogenous Reporters. Free Radic. Biol. Med.; 2012; 53, pp. 1807-1817. [DOI: https://dx.doi.org/10.1016/j.freeradbiomed.2012.08.015]

46. Zweier, J.L.; Hemann, C.; Kundu, T.; Ewees, M.G.; Khaleel, S.A.; Samouilov, A.; Ilangovan, G.; El-Mahdy, M.A. Cytoglobin Has Potent Superoxide Dismutase Function. Proc. Natl. Acad. Sci. USA; 2021; 118, e2105053118. [DOI: https://dx.doi.org/10.1073/pnas.2105053118] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/34930834]

47. You, X.; Tian, J.; Zhang, H.; Guo, Y.; Yang, J.; Zhu, C.; Song, M.; Wang, P.; Liu, Z.; Cancilla, J. et al. Loss of Mitochondrial Aconitase Promotes Colorectal Cancer Progression via SCD1-Mediated Lipid Remodeling. Mol. Metab.; 2021; 48, 101203. [DOI: https://dx.doi.org/10.1016/j.molmet.2021.101203]

48. Fenton, H.J.H. LXXIII.—Oxidation of Tartaric Acid in Presence of Iron. J. Chem. Soc. Trans.; 1894; 65, pp. 899-910. [DOI: https://dx.doi.org/10.1039/CT8946500899]

49. Wu, Y.; Lu, J.; Antony, S.; Juhasz, A.; Liu, H.; Jiang, G.; Meitzler, J.L.; Hollingshead, M.; Haines, D.C.; Butcher, D. et al. Activation of TLR4 Is Required for the Synergistic Induction of Dual Oxidase 2 and Dual Oxidase A2 by IFN-γ and Lipopolysaccharide in Human Pancreatic Cancer Cell Lines. J. Immunol.; 2013; 190, pp. 1859-1872. [DOI: https://dx.doi.org/10.4049/jimmunol.1201725] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/23296709]

50. Mochizuki, T.; Furuta, S.; Mitsushita, J.; Shang, W.H.; Ito, M.; Yokoo, Y.; Yamaura, M.; Ishizone, S.; Nakayama, J.; Konagai, A. et al. Inhibition of NADPH Oxidase 4 Activates Apoptosis via the AKT/Apoptosis Signal-Regulating Kinase 1 Pathway in Pancreatic Cancer PANC-1 Cells. Oncogene; 2006; 25, pp. 3699-3707. [DOI: https://dx.doi.org/10.1038/sj.onc.1209406]

51. Lee, J.K.; Edderkaoui, M.; Truong, P.; Ohno, I.; Jang, K.-T.; Berti, A.; Pandol, S.J.; Gukovskaya, A.S. NADPH Oxidase Promotes Pancreatic Cancer Cell Survival via Inhibiting JAK2 Dephosphorylation by Tyrosine Phosphatases. Gastroenterology; 2007; 133, pp. 1637-1648. [DOI: https://dx.doi.org/10.1053/j.gastro.2007.08.022]

52. Landry, W.D.; Cotter, T.G. ROS Signalling, NADPH Oxidases and Cancer. Biochem. Soc. Trans.; 2014; 42, pp. 934-938. [DOI: https://dx.doi.org/10.1042/BST20140060]

53. Moloney, J.N.; Cotter, T.G. ROS Signalling in the Biology of Cancer. Semin. Cell Dev. Biol.; 2018; 80, pp. 50-64. [DOI: https://dx.doi.org/10.1016/j.semcdb.2017.05.023]

54. Gorrini, C.; Harris, I.S.; Mak, T.W. Modulation of Oxidative Stress as an Anticancer Strategy. Nat. Rev. Drug Discov.; 2013; 12, pp. 931-947. [DOI: https://dx.doi.org/10.1038/nrd4002]

55. Dong, Y.; Zhang, M.; Liang, B.; Xie, Z.; Zhao, Z.; Asfa, S.; Choi, H.C.; Zou, M.-H. Reduction of AMP-Activated Protein Kinase Alpha2 Increases Endoplasmic Reticulum Stress and Atherosclerosis in Vivo. Circulation; 2010; 121, pp. 792-803. [DOI: https://dx.doi.org/10.1161/CIRCULATIONAHA.109.900928]

56. Ma, W.F.; Boudreau, H.E.; Leto, T.L. Pan-Cancer Analysis Shows TP53 Mutations Modulate the Association of NOX4 with Genetic Programs of Cancer Progression and Clinical Outcome. Antioxidants; 2021; 10, 235. [DOI: https://dx.doi.org/10.3390/antiox10020235] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33557266]

57. Lin, X.-L.; Yang, L.; Fu, S.-W.; Lin, W.-F.; Gao, Y.-J.; Chen, H.-Y.; Ge, Z.-Z. Overexpression of NOX4 Predicts Poor Prognosis and Promotes Tumor Progression in Human Colorectal Cancer. Oncotarget; 2017; 8, pp. 33586-33600. [DOI: https://dx.doi.org/10.18632/oncotarget.16829] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28422720]

58. Park, H.S.; Jung, H.Y.; Park, E.Y.; Kim, J.; Lee, W.J.; Bae, Y.S. Cutting Edge: Direct Interaction of TLR4 with NAD(P)H Oxidase 4 Isozyme Is Essential for Lipopolysaccharide-Induced Production of Reactive Oxygen Species and Activation of NF-Kappa B. J. Immunol.; 2004; 173, pp. 3589-3593. [DOI: https://dx.doi.org/10.4049/jimmunol.173.6.3589]

59. Dong, P.-T.; Zhan, Y.; Jusuf, S.; Hui, J.; Dagher, Z.; Mansour, M.K.; Cheng, J.-X. Photoinactivation of Catalase Sensitizes Candida Albicans and Candida Auris to ROS-Producing Agents and Immune Cells. Adv. Sci.; 2022; 9, e2104384. [DOI: https://dx.doi.org/10.1002/advs.202104384] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35119220]

60. Calvani, N.E.D.; De Marco Verissimo, C.; Jewhurst, H.L.; Cwiklinski, K.; Flaus, A.; Dalton, J.P. Two Distinct Superoxidase Dismutases (SOD) Secreted by the Helminth Parasite Fasciola Hepatica Play Roles in Defence against Metabolic and Host Immune Cell-Derived Reactive Oxygen Species (ROS) during Growth and Development. Antioxidants; 2022; 11, 1968. [DOI: https://dx.doi.org/10.3390/antiox11101968]

61. Fernandes, A.P.; Holmgren, A. Glutaredoxins: Glutathione-Dependent Redox Enzymes with Functions Far Beyond a Simple Thioredoxin Backup System. Antioxid. Redox Signal.; 2004; 6, pp. 63-74. [DOI: https://dx.doi.org/10.1089/152308604771978354]

62. Jones, D.P. Redox Potential of GSH/GSSG Couple: Assay and Biological Significance. Methods Enzym.; 2002; 348, pp. 93-112. [DOI: https://dx.doi.org/10.1016/s0076-6879(02)48630-2]

63. Ursini, F.; Maiorino, M.; Brigelius-Flohé, R.; Aumann, K.D.; Roveri, A.; Schomburg, D.; Flohé, L. Diversity of Glutathione Peroxidases. Methods Enzym.; 1995; 252, pp. 38-53. [DOI: https://dx.doi.org/10.1016/0076-6879(95)52007-4]

64. Zhang, W.; Gong, M.; Zhang, W.; Mo, J.; Zhang, S.; Zhu, Z.; Wang, X.; Zhang, B.; Qian, W.; Wu, Z. et al. Thiostrepton Induces Ferroptosis in Pancreatic Cancer Cells through STAT3/GPX4 Signalling. Cell Death Dis.; 2022; 13, 630. [DOI: https://dx.doi.org/10.1038/s41419-022-05082-3] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35859150]

65. Shin, D.; Kim, E.H.; Lee, J.; Roh, J.-L. Nrf2 Inhibition Reverses Resistance to GPX4 Inhibitor-Induced Ferroptosis in Head and Neck Cancer. Free Radic. Biol. Med.; 2018; 129, pp. 454-462. [DOI: https://dx.doi.org/10.1016/j.freeradbiomed.2018.10.426] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30339884]

66. Li, D.; Wang, T.; Lai, J.; Zeng, D.; Chen, W.; Zhang, X.; Zhu, X.; Zhang, G.; Hu, Z. Silencing TRPM2 Enhanced Erastin- and RSL3-Induced Ferroptosis in Gastric Cancer Cells through Destabilizing HIF-1α and Nrf2 Proteins. Cytotechnology; 2022; 74, pp. 559-577. [DOI: https://dx.doi.org/10.1007/s10616-022-00545-z] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36238268]

67. Buettner, R.G. Superoxide Dismutase in Redox Biology: The Roles of Superoxide and Hydrogen Peroxide. Anti-Cancer Agents Med. Chem. Anti-Cancer Agents; 2011; 11, pp. 341-346. [DOI: https://dx.doi.org/10.2174/187152011795677544]

68. Nie, S.; Shi, Z.; Shi, M.; Li, H.; Qian, X.; Peng, C.; Ding, X.; Zhang, S.; Lv, Y.; Wang, L. et al. PPARγ/SOD2 Protects Against Mitochondrial ROS-Dependent Apoptosis via Inhibiting ATG4D-Mediated Mitophagy to Promote Pancreatic Cancer Proliferation. Front. Cell Dev. Biol.; 2022; 9, 745554. [DOI: https://dx.doi.org/10.3389/fcell.2021.745554] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35186942]

69. Miao, Y.; Chen, Y.; Xue, F.; Liu, K.; Zhu, B.; Gao, J.; Yin, J.; Zhang, C.; Li, G. Contribution of Ferroptosis and GPX4′s Dual Functions to Osteoarthritis Progression. eBioMedicine; 2022; 76, 103847. [DOI: https://dx.doi.org/10.1016/j.ebiom.2022.103847]

70. Yuan, H.; Li, X.; Zhang, X.; Kang, R.; Tang, D. Identification of ACSL4 as a Biomarker and Contributor of Ferroptosis. Biochem. Biophys. Res. Commun.; 2016; 478, pp. 1338-1343. [DOI: https://dx.doi.org/10.1016/j.bbrc.2016.08.124]

71. Seiler, A.; Schneider, M.; Förster, H.; Roth, S.; Wirth, E.K.; Culmsee, C.; Plesnila, N.; Kremmer, E.; Rådmark, O.; Wurst, W. et al. Glutathione Peroxidase 4 Senses and Translates Oxidative Stress into 12/15-Lipoxygenase Dependent- and AIF-Mediated Cell Death. Cell Metab.; 2008; 8, pp. 237-248. [DOI: https://dx.doi.org/10.1016/j.cmet.2008.07.005]

72. Magtanong, L.; Ko, P.-J.; To, M.; Cao, J.Y.; Forcina, G.C.; Tarangelo, A.; Ward, C.C.; Cho, K.; Patti, G.J.; Nomura, D.K. et al. Exogenous Monounsaturated Fatty Acids Promote a Ferroptosis-Resistant Cell State. Cell Chem. Biol.; 2019; 26, pp. 420-432.e9. [DOI: https://dx.doi.org/10.1016/j.chembiol.2018.11.016]

73. Ye, Z.; Zhuo, Q.; Hu, Q.; Xu, X.; Liu, M.; Zhang, Z.; Xu, W.; Liu, W.; Fan, G.; Qin, Y. et al. FBW7-NRA41-SCD1 Axis Synchronously Regulates Apoptosis and Ferroptosis in Pancreatic Cancer Cells. Redox Biol.; 2021; 38, 101807. [DOI: https://dx.doi.org/10.1016/j.redox.2020.101807]

74. Tesfay, L.; Paul, B.T.; Konstorum, A.; Deng, Z.; Cox, A.O.; Lee, J.; Furdui, C.M.; Hegde, P.; Torti, F.M.; Torti, S.V. Stearoyl-CoA Desaturase 1 Protects Ovarian Cancer Cells from Ferroptotic Cell Death. Cancer Res.; 2019; 79, pp. 5355-5366. [DOI: https://dx.doi.org/10.1158/0008-5472.CAN-19-0369] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31270077]

75. Zhang, J.; Bajari, R.; Andric, D.; Gerthoffert, F.; Lepsa, A.; Nahal-Bose, H.; Stein, L.D.; Ferretti, V. The International Cancer Genome Consortium Data Portal. Nat. Biotechnol.; 2019; 37, pp. 367-369. [DOI: https://dx.doi.org/10.1038/s41587-019-0055-9] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30877282]

76. Cancer Genome Atlas Research Network. Comprehensive Genomic Characterization Defines Human Glioblastoma Genes and Core Pathways. Nature; 2008; 455, pp. 1061-1068. [DOI: https://dx.doi.org/10.1038/nature07385] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/18772890]

77. Majewski, I.J.; Bernards, R. Taming the Dragon: Genomic Biomarkers to Individualize the Treatment of Cancer. Nat. Med.; 2011; 17, pp. 304-312. [DOI: https://dx.doi.org/10.1038/nm.2311]

78. Bailey, P.; Chang, D.K.; Nones, K.; Johns, A.L.; Patch, A.-M.; Gingras, M.-C.; Miller, D.K.; Christ, A.N.; Bruxner, T.J.C.; Quinn, M.C. et al. Genomic Analyses Identify Molecular Subtypes of Pancreatic Cancer. Nature; 2016; 531, pp. 47-52. [DOI: https://dx.doi.org/10.1038/nature16965]

79. Singhi, A.D.; Wood, L.D. Early Detection of Pancreatic Cancer Using DNA-Based Molecular Approaches. Nat. Rev. Gastroenterol. Hepatol.; 2021; 18, pp. 457-468. [DOI: https://dx.doi.org/10.1038/s41575-021-00470-0]

80. Martinez-Useros, J.; Martin-Galan, M.; Garcia-Foncillas, J. The Match between Molecular Subtypes, Histology and Microenvironment of Pancreatic Cancer and Its Relevance for Chemoresistance. Cancers; 2021; 13, 322. [DOI: https://dx.doi.org/10.3390/cancers13020322]

81. Zheng, X.; Carstens, J.L.; Kim, J.; Scheible, M.; Kaye, J.; Sugimoto, H.; Wu, C.-C.; LeBleu, V.S.; Kalluri, R. Epithelial-to-Mesenchymal Transition Is Dispensable for Metastasis but Induces Chemoresistance in Pancreatic Cancer. Nature; 2015; 527, pp. 525-530. [DOI: https://dx.doi.org/10.1038/nature16064]

82. Jiang, Y.-Y.; Jiang, Y.; Li, C.-Q.; Zhang, Y.; Dakle, P.; Kaur, H.; Deng, J.-W.; Lin, R.Y.-T.; Han, L.; Xie, J.-J. et al. TP63, SOX2, and KLF5 Establish a Core Regulatory Circuitry That Controls Epigenetic and Transcription Patterns in Esophageal Squamous Cell Carcinoma Cell Lines. Gastroenterology; 2020; 159, pp. 1311-1327.e19. [DOI: https://dx.doi.org/10.1053/j.gastro.2020.06.050]

83. Zhao, T.; Ye, S.; Tang, Z.; Guo, L.; Ma, Z.; Zhang, Y.; Yang, C.; Peng, J.; Chen, J. Loss-of-Function of P53 Isoform Δ113p53 Accelerates Brain Aging in Zebrafish. Cell Death Dis.; 2021; 12, 151. [DOI: https://dx.doi.org/10.1038/s41419-021-03438-9]

84. Sablina, A.A.; Budanov, A.V.; Ilyinskaya, G.V.; Agapova, L.S.; Kravchenko, J.E.; Chumakov, P.M. The Antioxidant Function of the P53 Tumor Suppressor. Nat. Med.; 2005; 11, pp. 1306-1313. [DOI: https://dx.doi.org/10.1038/nm1320] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/16286925]

85. Cano, C.E.; Gommeaux, J.; Pietri, S.; Culcasi, M.; Garcia, S.; Seux, M.; Barelier, S.; Vasseur, S.; Spoto, R.P.; Pébusque, M.-J. et al. Tumor Protein 53-Induced Nuclear Protein 1 Is a Major Mediator of P53 Antioxidant Function. Cancer Res.; 2009; 69, pp. 219-226. [DOI: https://dx.doi.org/10.1158/0008-5472.CAN-08-2320] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/19118006]

86. Seillier, M.; Pouyet, L.; N’Guessan, P.; Nollet, M.; Capo, F.; Guillaumond, F.; Peyta, L.; Dumas, J.-F.; Varrault, A.; Bertrand, G. et al. Defects in Mitophagy Promote Redox-Driven Metabolic Syndrome in the Absence of TP53INP1. EMBO Mol. Med.; 2015; 7, pp. 802-818. [DOI: https://dx.doi.org/10.15252/emmm.201404318] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25828351]

87. Bae, S.H.; Sung, S.H.; Oh, S.Y.; Lim, J.M.; Lee, S.K.; Park, Y.N.; Lee, H.E.; Kang, D.; Rhee, S.G. Sestrins Activate Nrf2 by Promoting P62-Dependent Autophagic Degradation of Keap1 and Prevent Oxidative Liver Damage. Cell Metab.; 2013; 17, pp. 73-84. [DOI: https://dx.doi.org/10.1016/j.cmet.2012.12.002]

88. Chen, W.; Sun, Z.; Wang, X.-J.; Jiang, T.; Huang, Z.; Fang, D.; Zhang, D.D. Direct Interaction between Nrf2 and P21(Cip1/WAF1) Upregulates the Nrf2-Mediated Antioxidant Response. Mol. Cell; 2009; 34, pp. 663-673. [DOI: https://dx.doi.org/10.1016/j.molcel.2009.04.029]

89. Kalo, E.; Kogan-Sakin, I.; Solomon, H.; Bar-Nathan, E.; Shay, M.; Shetzer, Y.; Dekel, E.; Goldfinger, N.; Buganim, Y.; Stambolsky, P. et al. Mutant p53R273H Attenuates the Expression of Phase 2 Detoxifying Enzymes and Promotes the Survival of Cells with High Levels of Reactive Oxygen Species. J. Cell Sci.; 2012; 125, pp. 5578-5586. [DOI: https://dx.doi.org/10.1242/jcs.106815]

90. Singh, A.; Greninger, P.; Rhodes, D.; Koopman, L.; Violette, S.; Bardeesy, N.; Settleman, J. A Gene Expression Signature Associated with “K-Ras Addiction” Reveals Regulators of EMT and Tumor Cell Survival. Cancer Cell; 2009; 15, pp. 489-500. [DOI: https://dx.doi.org/10.1016/j.ccr.2009.03.022]

91. Weinberg, F.; Hamanaka, R.; Wheaton, W.W.; Weinberg, S.; Joseph, J.; Lopez, M.; Kalyanaraman, B.; Mutlu, G.M.; Budinger, G.R.S.; Chandel, N.S. Mitochondrial Metabolism and ROS Generation Are Essential for Kras-Mediated Tumorigenicity. Proc. Natl. Acad. Sci. USA; 2010; 107, pp. 8788-8793. [DOI: https://dx.doi.org/10.1073/pnas.1003428107]

92. Storz, P. KRas, ROS and the Initiation of Pancreatic Cancer. Small GTPases; 2017; 8, pp. 38-42. [DOI: https://dx.doi.org/10.1080/21541248.2016.1192714]

93. Liou, G.-Y.; Döppler, H.; DelGiorno, K.E.; Zhang, L.; Leitges, M.; Crawford, H.C.; Murphy, M.P.; Storz, P. Mutant KRas-Induced Mitochondrial Oxidative Stress in Acinar Cells Upregulates EGFR Signaling to Drive Formation of Pancreatic Precancerous Lesions. Cell Rep.; 2016; 14, pp. 2325-2336. [DOI: https://dx.doi.org/10.1016/j.celrep.2016.02.029]

94. Döppler, H.; Liou, G.-Y.; Storz, P. Downregulation of TRAF2 Mediates NIK-Induced Pancreatic Cancer Cell Proliferation and Tumorigenicity. PLoS ONE; 2013; 8, e53676. [DOI: https://dx.doi.org/10.1371/journal.pone.0053676] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/23301098]

95. Vaziri-Gohar, A.; Zarei, M.; Brody, J.R.; Winter, J.M. Metabolic Dependencies in Pancreatic Cancer. Front. Oncol.; 2018; 8, 617. [DOI: https://dx.doi.org/10.3389/fonc.2018.00617] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30631752]

96. DeNicola, G.M.; Karreth, F.A.; Humpton, T.J.; Gopinathan, A.; Wei, C.; Frese, K.; Mangal, D.; Yu, K.H.; Yeo, C.J.; Calhoun, E.S. et al. Oncogene-Induced Nrf2 Transcription Promotes ROS Detoxification and Tumorigenesis. Nature; 2011; 475, pp. 106-109. [DOI: https://dx.doi.org/10.1038/nature10189] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/21734707]

97. von Figura, G.; Morris, J.P.; Wright, C.V.E.; Hebrok, M. Nr5a2 Maintains Acinar Cell Differentiation and Constrains Oncogenic Kras-Mediated Pancreatic Neoplastic Initiation. Gut; 2014; 63, pp. 656-664. [DOI: https://dx.doi.org/10.1136/gutjnl-2012-304287]

98. Hale, M.A.; Swift, G.H.; Hoang, C.Q.; Deering, T.G.; Masui, T.; Lee, Y.-K.; Xue, J.; MacDonald, R.J. The Nuclear Hormone Receptor Family Member NR5A2 Controls Aspects of Multipotent Progenitor Cell Formation and Acinar Differentiation during Pancreatic Organogenesis. Development; 2014; 141, pp. 3123-3133. [DOI: https://dx.doi.org/10.1242/dev.109405]

99. Cowell, C.F.; Döppler, H.; Yan, I.K.; Hausser, A.; Umezawa, Y.; Storz, P. Mitochondrial Diacylglycerol Initiates Protein-Kinase D1-Mediated ROS Signaling. J. Cell Sci.; 2009; 122, pp. 919-928. [DOI: https://dx.doi.org/10.1242/jcs.041061]

100. Ardito, C.M.; Grüner, B.M.; Takeuchi, K.K.; Lubeseder-Martellato, C.; Teichmann, N.; Mazur, P.K.; Delgiorno, K.E.; Carpenter, E.S.; Halbrook, C.J.; Hall, J.C. et al. EGF Receptor Is Required for KRAS-Induced Pancreatic Tumorigenesis. Cancer Cell; 2012; 22, pp. 304-317. [DOI: https://dx.doi.org/10.1016/j.ccr.2012.07.024]

101. Hosein, A.N.; Brekken, R.A.; Maitra, A. Pancreatic Cancer Stroma: An Update on Therapeutic Targeting Strategies. Nat. Rev. Gastroenterol. Hepatol.; 2020; 17, pp. 487-505. [DOI: https://dx.doi.org/10.1038/s41575-020-0300-1]

102. Garrido-Martin, E.M.; Mellows, T.W.P.; Clarke, J.; Ganesan, A.-P.; Wood, O.; Cazaly, A.; Seumois, G.; Chee, S.J.; Alzetani, A.; King, E.V. et al. M1hot Tumor-Associated Macrophages Boost Tissue-Resident Memory T Cells Infiltration and Survival in Human Lung Cancer. J. Immunother. Cancer; 2020; 8, e000778. [DOI: https://dx.doi.org/10.1136/jitc-2020-000778]

103. Tanaka, S. Molecular Pathogenesis and Targeted Therapy of Pancreatic Cancer. Ann. Surg. Oncol.; 2016; 23, pp. 197-205. [DOI: https://dx.doi.org/10.1245/s10434-015-4463-x]

104. Jiang, X.; Stockwell, B.R.; Conrad, M. Ferroptosis: Mechanisms, Biology and Role in Disease. Nat. Rev. Mol. Cell Biol.; 2021; 22, pp. 266-282. [DOI: https://dx.doi.org/10.1038/s41580-020-00324-8] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33495651]

105. Chen, P.; Li, X.; Zhang, R.; Liu, S.; Xiang, Y.; Zhang, M.; Chen, X.; Pan, T.; Yan, L.; Feng, J. et al. Combinative Treatment of β-Elemene and Cetuximab Is Sensitive to KRAS Mutant Colorectal Cancer Cells by Inducing Ferroptosis and Inhibiting Epithelial-Mesenchymal Transformation. Theranostics; 2020; 10, pp. 5107-5119. [DOI: https://dx.doi.org/10.7150/thno.44705] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32308771]

106. Yang, J.; Mo, J.; Dai, J.; Ye, C.; Cen, W.; Zheng, X.; Jiang, L.; Ye, L. Cetuximab Promotes RSL3-Induced Ferroptosis by Suppressing the Nrf2/HO-1 Signalling Pathway in KRAS Mutant Colorectal Cancer. Cell Death Dis.; 2021; 12, 1079. [DOI: https://dx.doi.org/10.1038/s41419-021-04367-3] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/34775496]

107. Jiang, L.; Kon, N.; Li, T.; Wang, S.-J.; Su, T.; Hibshoosh, H.; Baer, R.; Gu, W. Ferroptosis as a P53-Mediated Activity during Tumour Suppression. Nature; 2015; 520, pp. 57-62. [DOI: https://dx.doi.org/10.1038/nature14344]

108. Bensaad, K.; Tsuruta, A.; Selak, M.A.; Vidal, M.N.C.; Nakano, K.; Bartrons, R.; Gottlieb, E.; Vousden, K.H. TIGAR, a P53-Inducible Regulator of Glycolysis and Apoptosis. Cell; 2006; 126, pp. 107-120. [DOI: https://dx.doi.org/10.1016/j.cell.2006.05.036]

109. Hu, W.; Zhang, C.; Wu, R.; Sun, Y.; Levine, A.; Feng, Z. Glutaminase 2, a Novel P53 Target Gene Regulating Energy Metabolism and Antioxidant Function. Proc. Natl. Acad. Sci. USA; 2010; 107, pp. 7455-7460. [DOI: https://dx.doi.org/10.1073/pnas.1001006107]

110. Liu, D.S.; Duong, C.P.; Haupt, S.; Montgomery, K.G.; House, C.M.; Azar, W.J.; Pearson, H.B.; Fisher, O.M.; Read, M.; Guerra, G.R. et al. Inhibiting the System xC-/Glutathione Axis Selectively Targets Cancers with Mutant-P53 Accumulation. Nat. Commun.; 2017; 8, 14844. [DOI: https://dx.doi.org/10.1038/ncomms14844]

111. Kesavardhana, S.; Malireddi, R.K.S.; Kanneganti, T.-D. Caspases in Cell Death, Inflammation, and Pyroptosis. Annu. Rev. Immunol.; 2020; 38, pp. 567-595. [DOI: https://dx.doi.org/10.1146/annurev-immunol-073119-095439]

112. Richard, D.; Kefi, K.; Barbe, U.; Bausero, P.; Visioli, F. Polyunsaturated Fatty Acids as Antioxidants. Pharmacol. Res.; 2008; 57, pp. 451-455. [DOI: https://dx.doi.org/10.1016/j.phrs.2008.05.002]

113. Yang, W.S.; Kim, K.J.; Gaschler, M.M.; Patel, M.; Shchepinov, M.S.; Stockwell, B.R. Peroxidation of Polyunsaturated Fatty Acids by Lipoxygenases Drives Ferroptosis. Proc. Natl. Acad. Sci. USA; 2016; 113, pp. E4966-E4975. [DOI: https://dx.doi.org/10.1073/pnas.1603244113]

114. Illés, E.; Patra, S.G.; Marks, V.; Mizrahi, A.; Meyerstein, D. The FeII(Citrate) Fenton Reaction under Physiological Conditions. J. Inorg. Biochem.; 2020; 206, 111018. [DOI: https://dx.doi.org/10.1016/j.jinorgbio.2020.111018]

115. Lopes, T.J.S.; Luganskaja, T.; Vujić Spasić, M.; Hentze, M.W.; Muckenthaler, M.U.; Schümann, K.; Reich, J.G. Systems Analysis of Iron Metabolism: The Network of Iron Pools and Fluxes. BMC Syst. Biol.; 2010; 4, 112. [DOI: https://dx.doi.org/10.1186/1752-0509-4-112] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/20704761]

116. Reeder, B.J.; Hider, R.C.; Wilson, M.T. Iron Chelators Can Protect against Oxidative Stress through Ferryl Heme Reduction. Free Radic. Biol. Med.; 2008; 44, pp. 264-273. [DOI: https://dx.doi.org/10.1016/j.freeradbiomed.2007.08.006] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/18215735]

117. Xu, C.; Sun, S.; Johnson, T.; Qi, R.; Zhang, S.; Zhang, J.; Yang, K. The Glutathione Peroxidase Gpx4 Prevents Lipid Peroxidation and Ferroptosis to Sustain Treg Cell Activation and Suppression of Antitumor Immunity. Cell Rep.; 2021; 35, 109235. [DOI: https://dx.doi.org/10.1016/j.celrep.2021.109235] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/34133924]

118. Bekkali, N.L.H.; Oppong, K.W. Pancreatic Ductal Adenocarcinoma Epidemiology and Risk Assessment: Could We Prevent? Possibility for an Early Diagnosis. Endosc. Ultrasound; 2017; 6, pp. S58-S61. [DOI: https://dx.doi.org/10.4103/eus.eus_60_17]

119. Tian, N.; Wu, D.; Zhu, L.; Zeng, M.; Li, J.; Wang, X. A Predictive Model for Recurrence after Upfront Surgery in Patients with Resectable Pancreatic Ductal Adenocarcinoma (PDAC) by Using Preoperative Clinical Data and CT Characteristics. BMC Med. Imaging; 2022; 22, 116. [DOI: https://dx.doi.org/10.1186/s12880-022-00823-4]

120. Groot, V.P.; Gemenetzis, G.; Blair, A.B.; Rivero-Soto, R.J.; Yu, J.; Javed, A.A.; Burkhart, R.A.; Rinkes, I.H.M.B.; Molenaar, I.Q.; Cameron, J.L. et al. Defining and Predicting Early Recurrence in 957 Patients With Resected Pancreatic Ductal Adenocarcinoma. Ann. Surg.; 2019; 269, pp. 1154-1162. [DOI: https://dx.doi.org/10.1097/SLA.0000000000002734]

121. Maisonneuve, P. Epidemiology and Burden of Pancreatic Cancer. La Presse Médicale; 2019; 48, pp. e113-e123. [DOI: https://dx.doi.org/10.1016/j.lpm.2019.02.030]

122. Ju, H.-Q.; Gocho, T.; Aguilar, M.; Wu, M.; Zhuang, Z.-N.; Fu, J.; Yanaga, K.; Huang, P.; Chiao, P.J. Mechanisms of Overcoming Intrinsic Resistance to Gemcitabine in Pancreatic Ductal Adenocarcinoma through the Redox Modulation. Mol. Cancer Ther.; 2015; 14, pp. 788-798. [DOI: https://dx.doi.org/10.1158/1535-7163.MCT-14-0420]

123. Manea, A.; Manea, S.A.; Gafencu, A.V.; Raicu, M. Regulation of NADPH Oxidase Subunit P22(Phox) by NF-kB in Human Aortic Smooth Muscle Cells. Arch. Physiol. Biochem.; 2007; 113, pp. 163-172. [DOI: https://dx.doi.org/10.1080/13813450701531235]

124. Lau, A.; Villeneuve, N.F.; Sun, Z.; Wong, P.K.; Zhang, D.D. Dual Roles of Nrf2 in Cancer. Pharmacol. Res.; 2008; 58, pp. 262-270. [DOI: https://dx.doi.org/10.1016/j.phrs.2008.09.003]

125. Eskandari, M.R.; Moghaddam, F.; Shahraki, J.; Pourahmad, J. A Comparison of Cardiomyocyte Cytotoxic Mechanisms for 5-Fluorouracil and Its pro-Drug Capecitabine. Xenobiotica; 2015; 45, pp. 79-87. [DOI: https://dx.doi.org/10.3109/00498254.2014.942809]

126. Liu, M.-P.; Liao, M.; Dai, C.; Chen, J.-F.; Yang, C.-J.; Liu, M.; Chen, Z.-G.; Yao, M.-C. Sanguisorba Officinalis L Synergistically Enhanced 5-Fluorouracil Cytotoxicity in Colorectal Cancer Cells by Promoting a Reactive Oxygen Species-Mediated, Mitochondria-Caspase-Dependent Apoptotic Pathway. Sci. Rep.; 2016; 6, 34245. [DOI: https://dx.doi.org/10.1038/srep34245]

127. Zhu, Q.; Guo, Y.; Chen, S.; Fu, D.; Li, Y.; Li, Z.; Ni, C. Irinotecan Induces Autophagy-Dependent Apoptosis and Positively Regulates ROS-Related JNK- and P38-MAPK Pathways in Gastric Cancer Cells. OncoTargets Ther.; 2020; 13, pp. 2807-2817. [DOI: https://dx.doi.org/10.2147/OTT.S240803] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32308415]

128. Liu, Y.; Shi, C.; He, Z.; Zhu, F.; Wang, M.; He, R.; Zhao, C.; Shi, X.; Zhou, M.; Pan, S. et al. Inhibition of PI3K/AKT Signaling via ROS Regulation Is Involved in Rhein-Induced Apoptosis and Enhancement of Oxaliplatin Sensitivity in Pancreatic Cancer Cells. Int. J. Biol. Sci.; 2021; 17, pp. 589-602. [DOI: https://dx.doi.org/10.7150/ijbs.49514] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33613115]

129. Ren, X.; Zhao, B.; Chang, H.; Xiao, M.; Wu, Y.; Liu, Y. Paclitaxel Suppresses Proliferation and Induces Apoptosis through Regulation of ROS and the AKT/MAPK Signaling Pathway in Canine Mammary Gland Tumor Cells. Mol. Med. Rep.; 2018; 17, pp. 8289-8299. [DOI: https://dx.doi.org/10.3892/mmr.2018.8868]

130. Carneiro, B.A.; El-Deiry, W.S. Targeting Apoptosis in Cancer Therapy. Nat. Rev. Clin. Oncol.; 2020; 17, pp. 395-417. [DOI: https://dx.doi.org/10.1038/s41571-020-0341-y]

131. Dodson, M.; Castro-Portuguez, R.; Zhang, D.D. NRF2 Plays a Critical Role in Mitigating Lipid Peroxidation and Ferroptosis. Redox Biol.; 2019; 23, 101107. [DOI: https://dx.doi.org/10.1016/j.redox.2019.101107] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30692038]

132. Redza-Dutordoir, M.; Averill-Bates, D.A. Activation of Apoptosis Signalling Pathways by Reactive Oxygen Species. Biochim. Biophys. Acta; 2016; 1863, pp. 2977-2992. [DOI: https://dx.doi.org/10.1016/j.bbamcr.2016.09.012] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/27646922]

133. Xu, M.; Rui, D.; Yan, Y.; Xu, S.; Niu, Q.; Feng, G.; Wang, Y.; Li, S.; Jing, M. Oxidative Damage Induced by Arsenic in Mice or Rats: A Systematic Review and Meta-Analysis. Biol. Trace Elem. Res.; 2017; 176, pp. 154-175. [DOI: https://dx.doi.org/10.1007/s12011-016-0810-4]

134. Li, X.; Ding, X.; Adrian, T.E. Arsenic Trioxide Induces Apoptosis in Pancreatic Cancer Cells via Changes in Cell Cycle, Caspase Activation, and GADD Expression. Pancreas; 2003; 27, pp. 174-179. [DOI: https://dx.doi.org/10.1097/00006676-200308000-00011] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/12883267]

135. Park, W.H.; Seol, J.G.; Kim, E.S.; Hyun, J.M.; Jung, C.W.; Lee, C.C.; Kim, B.K.; Lee, Y.Y. Arsenic Trioxide-Mediated Growth Inhibition in MC/CAR Myeloma Cells via Cell Cycle Arrest in Association with Induction of Cyclin-Dependent Kinase Inhibitor, P21, and Apoptosis. Cancer Res.; 2000; 60, pp. 3065-3071. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/10850458]

136. Loh, S.N. Arsenic and an Old Place: Rescuing P53 Mutants in Cancer. Cancer Cell; 2021; 39, pp. 140-142. [DOI: https://dx.doi.org/10.1016/j.ccell.2021.01.012] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33561393]

137. Ma, Y.-F.; Lu, Y.; Wu, Q.; Lou, Y.-J.; Yang, M.; Xu, J.-Y.; Sun, C.-H.; Mao, L.-P.; Xu, G.-X.; Li, L. et al. Oral Arsenic and Retinoic Acid for High-Risk Acute Promyelocytic Leukemia. J. Hematol. Oncol.; 2022; 15, 148. [DOI: https://dx.doi.org/10.1186/s13045-022-01368-3]

138. Kindler, H.L.; Aklilu, M.; Nattam, S.; Vokes, E.E. Arsenic Trioxide in Patients with Adenocarcinoma of the Pancreas Refractory to Gemcitabine: A Phase II Trial of the University of Chicago Phase II Consortium. Am. J. Clin. Oncol.; 2008; 31, pp. 553-556. [DOI: https://dx.doi.org/10.1097/COC.0b013e318178e4cd]

139. Yun, J.; Mullarky, E.; Lu, C.; Bosch, K.N.; Kavalier, A.; Rivera, K.; Roper, J.; Chio, I.I.C.; Giannopoulou, E.G.; Rago, C. et al. Vitamin C Selectively Kills KRAS and BRAF Mutant Colorectal Cancer Cells by Targeting GAPDH. Science; 2015; 350, pp. 1391-1396. [DOI: https://dx.doi.org/10.1126/science.aaa5004]

140. Yamaguchi, Y.; Kasukabe, T.; Kumakura, S. Piperlongumine Rapidly Induces the Death of Human Pancreatic Cancer Cells Mainly through the Induction of Ferroptosis. Int. J. Oncol.; 2018; 52, pp. 1011-1022. [DOI: https://dx.doi.org/10.3892/ijo.2018.4259] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/29393418]

141. Eling, N.; Reuter, L.; Hazin, J.; Hamacher-Brady, A.; Brady, N.R. Identification of Artesunate as a Specific Activator of Ferroptosis in Pancreatic Cancer Cells. Oncoscience; 2015; 2, pp. 517-532. [DOI: https://dx.doi.org/10.18632/oncoscience.160] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/26097885]

142. Zhang, Y.; Tan, H.; Daniels, J.D.; Zandkarimi, F.; Liu, H.; Brown, L.M.; Uchida, K.; O’Connor, O.A.; Stockwell, B.R. Imidazole Ketone Erastin Induces Ferroptosis and Slows Tumor Growth in a Mouse Lymphoma Model. Cell Chem. Biol.; 2019; 26, pp. 623-633.e9. [DOI: https://dx.doi.org/10.1016/j.chembiol.2019.01.008]

143. Cramer, S.L.; Saha, A.; Liu, J.; Tadi, S.; Tiziani, S.; Yan, W.; Triplett, K.; Lamb, C.; Alters, S.E.; Rowlinson, S. et al. Systemic Depletion of L-Cyst(e)Ine with Cyst(e)Inase Increases Reactive Oxygen Species and Suppresses Tumor Growth. Nat. Med.; 2017; 23, pp. 120-127. [DOI: https://dx.doi.org/10.1038/nm.4232]

144. Zhang, Y.; Huang, Z.; Cheng, J.; Pan, H.; Lin, T.; Shen, X.; Chen, W.; Chen, Q.; Gu, C.; Mao, Q. et al. Platelet-Vesicles-Encapsulated RSL-3 Enable Anti-Angiogenesis and Induce Ferroptosis to Inhibit Pancreatic Cancer Progress. Front. Endocrinol.; 2022; 13, 865655. [DOI: https://dx.doi.org/10.3389/fendo.2022.865655] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35399954]

145. Lee, W.; Song, G.; Bae, H. Laminarin Attenuates ROS-Mediated Cell Migration and Invasiveness through Mitochondrial Dysfunction in Pancreatic Cancer Cells. Antioxidants; 2022; 11, 1714. [DOI: https://dx.doi.org/10.3390/antiox11091714] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36139787]

146. Abdel Hadi, N.; Reyes-Castellanos, G.; Carrier, A. Targeting Redox Metabolism in Pancreatic Cancer. Int. J. Mol. Sci.; 2021; 22, 1534. [DOI: https://dx.doi.org/10.3390/ijms22041534]

147. Tsuchiya, Y.; Zhyvoloup, A.; Baković, J.; Thomas, N.; Yu, B.Y.K.; Das, S.; Orengo, C.; Newell, C.; Ward, J.; Saladino, G. et al. Protein CoAlation and Antioxidant Function of Coenzyme A in Prokaryotic Cells. Biochem. J.; 2018; 475, pp. 1909-1937. [DOI: https://dx.doi.org/10.1042/BCJ20180043]

148. Trujillo, M.; Clippe, A.; Manta, B.; Ferrer-Sueta, G.; Smeets, A.; Declercq, J.-P.; Knoops, B.; Radi, R. Pre-Steady State Kinetic Characterization of Human Peroxiredoxin 5: Taking Advantage of Trp84 Fluorescence Increase upon Oxidation. Arch. Biochem. Biophys.; 2007; 467, pp. 95-106. [DOI: https://dx.doi.org/10.1016/j.abb.2007.08.008]

149. Zhang, Y.; Ikeno, Y.; Qi, W.; Chaudhuri, A.; Li, Y.; Bokov, A.; Thorpe, S.R.; Baynes, J.W.; Epstein, C.; Richardson, A. et al. Mice Deficient in Both Mn Superoxide Dismutase and Glutathione Peroxidase-1 Have Increased Oxidative Damage and a Greater Incidence of Pathology but No Reduction in Longevity. J. Gerontol. Ser. A; 2009; 64A, pp. 1212-1220. [DOI: https://dx.doi.org/10.1093/gerona/glp132]

150. Barrett, C.W.; Ning, W.; Chen, X.; Smith, J.J.; Washington, M.K.; Hill, K.E.; Coburn, L.A.; Peek, R.M.; Chaturvedi, R.; Wilson, K.T. et al. Tumor Suppressor Function of the Plasma Glutathione Peroxidase Gpx3 in Colitis-Associated Carcinoma. Cancer Res.; 2013; 73, pp. 1245-1255. [DOI: https://dx.doi.org/10.1158/0008-5472.CAN-12-3150] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/23221387]

151. Cheung, E.C.; DeNicola, G.M.; Nixon, C.; Blyth, K.; Labuschagne, C.F.; Tuveson, D.A.; Vousden, K.H. Dynamic ROS Control by TIGAR Regulates the Initiation and Progression of Pancreatic Cancer. Cancer Cell; 2020; 37, pp. 168-182.e4. [DOI: https://dx.doi.org/10.1016/j.ccell.2019.12.012]

152. Ke, D.Y.J.; El-Sahli, S.; Wang, L. The Potential of Natural Products in the Treatment of Triple-Negative Breast Cancer. Curr. Cancer Drug Targets; 2022; 22, pp. 388-403. [DOI: https://dx.doi.org/10.2174/1568009622666211231140623]

153. Auyeung, K.K.-W.; Ko, J.K.-S. Novel Herbal Flavonoids Promote Apoptosis but Differentially Induce Cell Cycle Arrest in Human Colon Cancer Cell. Investig. New Drugs; 2010; 28, pp. 1-13. [DOI: https://dx.doi.org/10.1007/s10637-008-9207-3]

154. Husain, K.; Centeno, B.A.; Coppola, D.; Trevino, J.; Sebti, S.M.; Malafa, M.P. δ-Tocotrienol, a Natural Form of Vitamin E, Inhibits Pancreatic Cancer Stem-like Cells and Prevents Pancreatic Cancer Metastasis. Oncotarget; 2017; 8, pp. 31554-31567. [DOI: https://dx.doi.org/10.18632/oncotarget.15767] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28404939]

155. Arlt, A.; Sebens, S.; Krebs, S.; Geismann, C.; Grossmann, M.; Kruse, M.-L.; Schreiber, S.; Schäfer, H. Inhibition of the Nrf2 Transcription Factor by the Alkaloid Trigonelline Renders Pancreatic Cancer Cells More Susceptible to Apoptosis through Decreased Proteasomal Gene Expression and Proteasome Activity. Oncogene; 2013; 32, pp. 4825-4835. [DOI: https://dx.doi.org/10.1038/onc.2012.493] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/23108405]

156. Zhang, W.; Zhu, Y.; Yu, H.; Liu, X.; Jiao, B.; Lu, X. Libertellenone H, a Natural Pimarane Diterpenoid, Inhibits Thioredoxin System and Induces ROS-Mediated Apoptosis in Human Pancreatic Cancer Cells. Molecules; 2021; 26, 315. [DOI: https://dx.doi.org/10.3390/molecules26020315] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33435380]

157. Yu, L.; Chen, M.; Zhang, R.; Jin, Z. Inhibition of Cancer Cell Growth in Gemcitabine-Resistant Pancreatic Carcinoma by Mangiferin Phytochemical Involves Induction of Autophagy, Endogenous ROS Production, Cell Cycle Disruption, Mitochondrial Mediated Apoptosis and Suppression of Cancer Cell Migration and Invasion. J. BUON; 2019; 24, pp. 1581-1586.

158. du Plessis-Stoman, D.; du Preez, J.; van de Venter, M. Combination Treatment with Oxaliplatin and Mangiferin Causes Increased Apoptosis and Downregulation of NFκB in Cancer Cell Lines. Afr. J. Tradit. Complement. Altern. Med.; 2011; 8, pp. 177-184. [DOI: https://dx.doi.org/10.4314/ajtcam.v8i2.63206]

159. Wang, Z.-X.; Ma, J.; Li, X.-Y.; Wu, Y.; Shi, H.; Chen, Y.; Lu, G.; Shen, H.-M.; Lu, G.-D.; Zhou, J. Quercetin Induces P53-Independent Cancer Cell Death through Lysosome Activation by the Transcription Factor EB and Reactive Oxygen Species-Dependent Ferroptosis. Br. J. Pharmacol.; 2021; 178, pp. 1133-1148. [DOI: https://dx.doi.org/10.1111/bph.15350]

160. Kasukabe, T.; Honma, Y.; Okabe-Kado, J.; Higuchi, Y.; Kato, N.; Kumakura, S. Combined Treatment with Cotylenin A and Phenethyl Isothiocyanate Induces Strong Antitumor Activity Mainly through the Induction of Ferroptotic Cell Death in Human Pancreatic Cancer Cells. Oncol. Rep.; 2016; 36, pp. 968-976. [DOI: https://dx.doi.org/10.3892/or.2016.4867]

161. Kasukabe, T.; Okabe-Kado, J.; Kato, N.; Honma, Y.; Kumakura, S. Cotylenin A and Arsenic Trioxide Cooperatively Suppress Cell Proliferation and Cell Invasion Activity in Human Breast Cancer Cells. Int. J. Oncol.; 2015; 46, pp. 841-848. [DOI: https://dx.doi.org/10.3892/ijo.2014.2760]

162. Lee, H.; Zandkarimi, F.; Zhang, Y.; Meena, J.K.; Kim, J.; Zhuang, L.; Tyagi, S.; Ma, L.; Westbrook, T.F.; Steinberg, G.R. et al. Energy-Stress-Mediated AMPK Activation Inhibits Ferroptosis. Nat. Cell Biol.; 2020; 22, pp. 225-234. [DOI: https://dx.doi.org/10.1038/s41556-020-0461-8]