DNA damage by lipid peroxidation products: implications in cancer, inflammation and autoimmunity

Gentile, Fabrizio; Arcaro, Alessia; Pizzimenti, Stefania; Daga, Martina; Cetrangolo, Giovanni Paolo; Dianzani, Chiara; Lepore, Alessio; Graf, Maria; Ames, P. R. J.; Barrera, Giuseppina

doi:10.3934/genet.2017.2.103

Cited by 141 publications

(112 citation statements)

References 178 publications

(222 reference statements)

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“…Moreover, the concomitant production of 8-OH-dG by ODD, discussed above, may enhance the epigenetic effect, as this adduct was shown to increase cytosine methylation at the -*CpG-islands [99]. On the other hand, it is well established that reactive LPO-induced aldehydes are more mutagenic than the free radicals and the highly reactive AFBO [83]. Indeed, reactive aldehydes can act remotely from the site of their formation, contrary to the short-lived and highly instable free radicals and epoxides.…”

Section: Oxidative Stress-mediated Genotoxicitymentioning

confidence: 99%

“…As was mentioned above, AFB1 can also induce DNA damage by OS indirectly via the production of ROS which, in turn, attack oxidatively membrane phospholipids and release different mutagenic aldehydes (Figure 1). Among 33 known LPO-derived aldehydes, malondialdehyde (MDA), acrolein (Acr), 4-hydroxy-2-nonenal (HNE), and 4-oxo-2(E)-nonenal (ONE) are the most predominant and can react with DNA bases to generate pro-mutagenic exocyclic DNA adducts leading to genomic instability and possibly to carcinogenicity [83][84][85][86][87][88][89]. For example, acetaldehyde (Ace), Acr, Cro, and HNE can bind to the DNA guanine residue to from the highly mutagenic 1,N 2 -propano-2 -deoxyguanosine (1,N 2 -propanodGuo, 1,N 2 -PdG) adduct [70,88,[90][91][92].…”

Section: Oxidative Stress-mediated Genotoxicitymentioning

confidence: 99%

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Chronic and Acute Toxicities of Aflatoxins: Mechanisms of Action

Benkerroum

2020

IJERPH

350

214

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There are presently more than 18 known aflatoxins most of which have been insufficiently studied for their incidence, health-risk, and mechanisms of toxicity to allow effective intervention and control means that would significantly and sustainably reduce their incidence and adverse effects on health and economy. Among these, aflatoxin B1 (AFB1) has been by far the most studied; yet, many aspects of the range and mechanisms of the diseases it causes remain to be elucidated. Its mutagenicity, tumorigenicity, and carcinogenicity—which are the best known—still suffer from limitations regarding the relative contribution of the oxidative stress and the reactive epoxide derivative (Aflatoxin-exo 8,9-epoxide) in the induction of the diseases, as well as its metabolic and synthesis pathways. Additionally, despite the well-established additive effects for carcinogenicity between AFB1 and other risk factors, e.g., hepatitis viruses B and C, and the hepatotoxic algal microcystins, the mechanisms of this synergy remain unclear. This study reviews the most recent advances in the field of the mechanisms of toxicity of aflatoxins and the adverse health effects that they cause in humans and animals.

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Section: Oxidative Stress-mediated Genotoxicitymentioning

confidence: 99%

Section: Oxidative Stress-mediated Genotoxicitymentioning

confidence: 99%

Chronic and Acute Toxicities of Aflatoxins: Mechanisms of Action

Benkerroum

2020

IJERPH

350

214

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“…A consensus exists that RAs play a dual role in cellular processes: They are known to modify proteins [49][50][51], DNA [52,53], and lipids [16,54], but are also involved in important signaling pathways [50]. However, the molecular mechanisms of their action are still far from being well understood.…”

Section: Mechanisms Of Ra Actionmentioning

confidence: 99%

The Role of Phosphatidylethanolamine Adducts in Modification of the Activity of Membrane Proteins under Oxidative Stress

Pohl

Jovanović

2019

Molecules

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Reactive oxygen species (ROS) and their derivatives, reactive aldehydes (RAs), have been implicated in the pathogenesis of many diseases, including metabolic, cardiovascular, and inflammatory disease. Understanding how RAs can modify the function of membrane proteins is critical for the design of therapeutic approaches in the above-mentioned pathologies. Over the last few decades, direct interactions of RA with proteins have been extensively studied. Yet, few studies have been performed on the modifications of membrane lipids arising from the interaction of RAs with the lipid amino group that leads to the formation of adducts. It is even less well understood how various multiple adducts affect the properties of the lipid membrane and those of embedded membrane proteins. In this short review, we discuss a crucial role of phosphatidylethanolamine (PE) and PE-derived adducts as mediators of RA effects on membrane proteins. We propose potential PE-mediated mechanisms that explain the modulation of membrane properties and the functions of membrane transporters, channels, receptors, and enzymes. We aim to highlight this new area of research and to encourage a more nuanced investigation of the complex nature of the new lipid-mediated mechanism in the modification of membrane protein function under oxidative stress.

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“…In addition, the carbonyl products of lipid peroxidation (such as malondialdehyde) can also attack the amino groups of membrane protein molecules, resulting in intramolecular and intermolecular cross-linking of proteins. On the other hand, free radicals can also covalently bind directly to enzymes or receptors on the membrane [29][30][31][32]. These oxidations damage the spatial con guration of enzymes, receptors and ion channels embedded in the membrane system, destroying the integrity of the membrane and affecting the function of the membrane and antigen speci city, which eventually leads to the cell damage and lesions.…”

Section: Disscussionmentioning

confidence: 99%

Pathological mechanism of hidden blood loss after TKA: oxidative stress induced by free fatty acids

Yuan¹,

Yu²,

Qian³

et al. 2020

Preprint

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Objective: To study the correlation between high-level free fat acids（FFA）and red blood cell (RBC) injury and to explore the pathological mechanism of hidden blood loss (HBL) after total knee arthroplasty (TKA).Methods: Perioperative blood indexes were tested in 120 patients underwent unilateral total knee replacement for end-stage knee osteoarthritis. Venous blood samples were collected before operation and 24h, 48h, 72h and 120 h after operations. The changes of FFA, hemoglobin (Hb) and red blood cell number in the blood samples were detected by automatic hematology analyzer. The activity of glutathion peroxidase (GSH-Px), total superoxide dismutase (T-SOD) and hydrogen peroxide (H2O2) levels in the blood were measured. Measurement of reactive oxygen species（ROS）was performed by flow cytometry. Meanwhile, the morphological changes of RBC were analyzed under microscope. Results: Significant hidden blood loss was observed for all patients. The Hb content, RBC and hematocrit（Hct）decreased significantly 24 h after surgery (P <0.05)，while FFA concentration was significantly increased and heteromorphic red blood cells appeared under the microscope. The hemoglobin content decreased to the lowest level at 48 h after the operation (P < 0.01). The change of HBL was the most significant according to the Gross equation with the levels of FFA and ROS in the blood increased significantly and reached the peak at 48 h after operation (P <0.01). Meanwhile, GSH-PX activity, T-SOD activity and H2O2 levels significantly decreased compared with preoperative tested samples (P <0.01). Microscopically, erythrocyte atypia increased significantly with cellular rupture and necrosis identified. After 72 h of operation, ROS concentration began to decline along with FFA concentration. However, the Hb and RBC began to rise. Also, GSH-Px activity, T-SOD activity and H2O2 levels increased as well. All tested parameters tended to return to normal levels five days after surgery.Conclusion: High levels of FFA in blood can induce oxidative stress and damage RBCs, which in turns causes HBL after surgery.

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DNA damage by lipid peroxidation products: implications in cancer, inflammation and autoimmunity

Cited by 141 publications

References 178 publications

Chronic and Acute Toxicities of Aflatoxins: Mechanisms of Action

Chronic and Acute Toxicities of Aflatoxins: Mechanisms of Action

The Role of Phosphatidylethanolamine Adducts in Modification of the Activity of Membrane Proteins under Oxidative Stress

Pathological mechanism of hidden blood loss after TKA: oxidative stress induced by free fatty acids

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