α-tocopherol inhibits atherogenesis and improves cardiac function in mice independently of its antioxidant properties.

The impact of α-tocopherol on atherosclerosis is unclear and controversial. While some studies suggest potential benefits, such as antioxidant properties that may reduce oxidative stress, other research indicates no significant preventive effects. The intricate interplay of various factors, including dosage, individual differences, and study methodologies, contributes to the ongoing uncertainty surrounding α-tocopherol's role in atherosclerosis. Further research is needed to clarify its impact and establish clearer guidelines. Therefore, we aimed to evaluate the impact of α-tocopherol on atherogenesis in ApoE-/- fibrillin (Fbn)1C1039G/+ mice, which is a unique mouse model of advanced atherosclerosis with typical features such as large necrotic cores, high levels of inflammation and intraplaque neovascularization that resemble the unstable phenotype of human plaques. ApoE-/- Fbn1C1039G+/- mice were fed a western-type diet (WD) supplemented with a high dose of α-tocopherol (500 mg/kg diet), while control mice were fed a WD containing a low dose of α-tocopherol (50 mg/kg diet). The high dose of α-tocopherol reduced plaque thickness and necrotic core area in the right common carotid artery (RCCA) after 24 weeks WD. Moreover, α-tocopherol decreased plaque formation and intraplaque neovascularization in the RCCA. In addition to its antiatherogenic effect, chronic supplementation of α-tocopherol improved cardiac function in ApoE-/- Fbn1C1039G/+ mice. However, chronic supplementation of α-tocopherol did not decrease lipid peroxidation. On the contrary, α-tocopherol acted as a prooxidant by increasing plasma levels of oxidized LDL and plaque malondialdehyde, an end product of lipid peroxidation. Our data indicate that α-tocopherol inhibits atherogenesis and improves cardiac function independent of its antioxidant properties.

GPX4 overexpression does not alter atherosclerotic plaque development in ApoE knock-out mice.

Ferroptosis is a type of regulated necrosis that is associated with iron-dependent accumulation of lipid hydroperoxides. Given that iron deposition and lipid peroxidation initiate ferroptosis in atherosclerosis and contribute to further plaque development, we hypothesized that inhibition of ferroptosis could be of value in the treatment of atherosclerosis. Glutathione peroxidase 4 (GPX4) is the only enzyme known capable of reducing lipid hydroperoxides. Previous studies have demonstrated that inactivation of GPX4 results in ferroptosis while overexpression of GPX4 confers resistance to ferroptosis. In the present study, we examined the impact of GPX4 overexpression on the development of atherosclerotic plaques. GPX4-overexpressing mice (GPX4Tg/+) were crossbred with ApoE-/- mice and fed a western-type diet for 16 weeks. Atherosclerotic plaques of GPX4Tg/+ ApoE-/- mice showed increased GPX4 expression and a reduced amount of lipid hydroperoxides. However, plaque size and composition were not different as compared to control animals. Similarly, GPX4-overexpressing vascular smooth muscle cells and bone-marrow derived macrophages were not protected against lipid peroxidation and cell death triggered by the ferroptosis inducers erastin and 1S,3RRSL3. We concluded that GPX4 overexpression reduces lipid peroxidation in plaques of ApoE-/- mice, yet GPX4 overexpression is not sufficiently powerful to change plaque size or composition.

The Impact of RIPK1 Kinase Inhibition on Atherogenesis: A Genetic and a Pharmacological Approach.

RIPK1 (receptor-interacting serine/threonine-protein kinase 1) enzymatic activity drives both apoptosis and necroptosis, a regulated form of necrosis. Because necroptosis is involved in necrotic core development in atherosclerotic plaques, we investigated the effects of a RIPK1S25D/S25D mutation, which prevents activation of RIPK1 kinase, on atherogenesis in ApoE-/- mice. After 16 weeks of western-type diet (WD), atherosclerotic plaques from ApoE-/- RIPK1S25D/S25D mice were significantly larger compared to ApoE-/- RIPK1+/+ mice (167 ± 34 vs. 78 ± 18 × 103 µm2, p = 0.01). Cell numbers (350 ± 34 vs. 154 ± 33 nuclei) and deposition of glycosaminoglycans (Alcian blue: 31 ± 6 vs. 14 ± 4%, p = 0.023) were increased in plaques from ApoE-/- RIPK1S25D/S25D mice while macrophage content (Mac3: 2.3 ± 0.4 vs. 9.8 ± 2.4%, p = 0.012) was decreased. Plaque apoptosis was not different between both groups. In contrast, pharmacological inhibition of RIPK1 kinase with GSK'547 (10 mg/kg BW/day) in ApoE-/- Fbn1C1039G+/- mice, a model of advanced atherosclerosis, did not alter plaque size after 20 weeks WD, but induced apoptosis (TUNEL: 136 ± 20 vs. 62 ± 9 cells/mm2, p = 0.004). In conclusion, inhibition of RIPK1 kinase activity accelerated plaque progression in ApoE-/- RIPK1S25D/S25D mice and induced apoptosis in GSK'547-treated ApoE-/- Fbn1C1039G+/- mice. Thus, without directly comparing the genetic and pharmacological studies, it can be concluded that targeting RIPK1 kinase activity does not limit atherogenesis.

GSK-7975A, an inhibitor of Ca2+ release-activated calcium channels, depresses isometric contraction of mouse aorta.

GSK-7975A is described to inhibit stromal interaction molecule 1(STIM1)-mediated Ca2+ release-activated Ca2+ channels ORAI 1, ORAI 2 and ORAI 3 in different cell types. The present study investigated whether isometric contractions of mouse aortic segments were affected by this selective store-operated calcium channel inhibitor. Depending on the way by which Ca2+ influx pathways were activated during contraction, GSK-7975A inhibited contractility of mouse aortic segments with different affinity. When contractile effects were induced by depolarization as with elevated extracellular K+ and opening of voltage-gated calcium channels, the affinity was approximately 10 times lower than when contraction was elicited with Ca2+ influx via non-selective cation channels. GSK-7975A may repolarize the aortic smooth muscle cells by inhibiting non-selective cation channels, has no effect on IP3-mediated phenylephrine-induced phasic contractions or on refilling of the contractile sarcoplasmic reticulum Ca2+ store, but has significant effects on non-contractile store-operated Ca2+ influx.

Impact of myeloid RIPK1 gene deletion on atherogenesis in ApoE-deficient mice.

BACKGROUND AND AIMS: Targeting macrophage death is a promising strategy for stabilizing atherosclerotic plaques. Recently, necroptosis was identified as a form of regulated necrosis in atherosclerosis. Receptor-interacting serine/threonine-protein kinase (RIPK)1 is an upstream regulator of RIPK3, which is a crucial kinase for necroptosis induction. We aimed to investigate the impact of myeloid-specific RIPK1 gene deletion on atherogenesis. METHODS: RIPK1F/FLysM-Cre+ApoE-/- and RIPK1+/+LysM-Cre+ApoE-/- mice were fed a western-type diet (WD) for 16 or 24 weeks to induce plaque formation. RESULTS: After 16 weeks WD, plaque area and percentage necrosis in RIPK1F/FLysM-Cre+ApoE-/- mice were significantly decreased as compared to plaques of RIPK1+/+LysM-Cre+ApoE-/- mice. Moreover, plaques of RIPK1F/FLysM-Cre+ApoE-/- mice showed more apoptosis and a decreased macrophage content. After 24 weeks WD, plaque size and percentage necrosis were no longer different between the two groups. Free apoptotic cells strongly accumulated in plaques of RIPK1F/FLysM-Cre+ApoE-/- mice. In addition to apoptosis, necroptosis was upregulated in plaques of RIPK1F/FLysM-Cre+ApoE-/- mice. In vitro, TNF-α triggered apoptosis in RIPK1F/FLysM-Cre+ApoE-/-, but not in RIPK1+/+LysM-Cre+ApoE-/- macrophages. Moreover, RIPK1F/FLysM-Cre+ApoE-/- macrophages were not protected against RIPK3-dependent necroptosis. CONCLUSIONS: The impact of myeloid RIPK1 gene deletion depends on the stage of atherogenesis. At 16 weeks WD, myeloid RIPK1 gene deletion resulted in increased apoptosis, thereby slowing down plaque progression. However, despite decreased macrophage content, plaque and necrotic core size were no longer reduced after 24 weeks of WD, most likely due to the accumulation of free apoptotic and necroptotic cells.

Macrophage Death as a Pharmacological Target in Atherosclerosis.

Atherosclerosis is a chronic inflammatory disorder characterized by the gradual build-up of plaques within the vessel wall of middle-sized and large arteries. Over the past decades, treatment of atherosclerosis mainly focused on lowering lipid levels, which can be accomplished by the use of statins. However, some patients do not respond sufficiently to statin therapy and therefore still have a residual cardiovascular risk. This issue highlights the need for novel therapeutic strategies. As macrophages are implicated in all stages of atherosclerotic lesion development, they represent an important alternative drug target. A variety of anti-inflammatory strategies have recently emerged to treat or prevent atherosclerosis. Here, we review the canonical mechanisms of macrophage death and their impact on atherogenesis and plaque stability. Macrophage death is a prominent feature of advanced plaques and is a major contributor to necrotic core formation and plaque destabilization. Mechanisms of macrophage death in atherosclerosis include apoptosis, passive or accidental necrosis as well as secondary necrosis, a type of death that typically occurs when apoptotic cells are insufficiently cleared by neighboring cells via a phagocytic process termed efferocytosis. In addition, less-well characterized types of regulated necrosis in macrophages such as necroptosis, pyroptosis, ferroptosis, and parthanatos may occur in advanced plaques and are also discussed. Autophagy in plaque macrophages is an important survival pathway that protects against cell death, yet massive stimulation of autophagy promotes another type of death, usually referred to as autosis. Multiple lines of evidence indicate that a better insight into the different mechanisms of macrophage death, and how they mutually interact, will provide novel pharmacological strategies to resolve atherosclerosis and stabilize vulnerable, rupture-prone plaques.

Novel drug discovery strategies for atherosclerosis that target necrosis and necroptosis.

INTRODUCTION: Formation and enlargement of a necrotic core play a pivotal role in atherogenesis. Since the discovery of necroptosis, which is a regulated form of necrosis, prevention of necrotic cell death has become an attractive therapeutic goal to reduce plaque formation. Areas covered: This review highlights the triggers and consequences of (unregulated) necrosis and necroptosis in atherosclerosis. The authors discuss different pharmacological strategies to inhibit necrotic cell death in advanced atherosclerotic plaques. Expert opinion: Addition of a necrosis or necroptosis inhibitor to standard statin therapy could be a promising strategy for primary prevention of cardiovascular disease. However, a necrosis inhibitor cannot block all necrosis stimuli in atherosclerotic plaques. A necroptosis inhibitor could be more effective, because necroptosis is mediated by specific proteins, termed receptor-interacting serine/threonine-protein kinases (RIPK) and mixed lineage kinase domain-like pseudokinase (MLKL). Currently, only RIPK1 inhibitors have been successfully used in atherosclerotic mouse models to inhibit necroptosis. However, because RIPK1 is involved in both necroptosis and apoptosis, and also RIPK1-independent necroptosis can occur, we feel that targeting RIPK3 and MLKL could be a more attractive therapeutic approach to inhibit necroptosis. Therefore, future challenges will consist of developing RIPK3 and MLKL inhibitors applicable in both preclinical and clinical settings.