Canonical cellular stress granules are required for arsenite-induced necroptosis mediated by Z-DNA-binding protein 1

Ferroptosis-activating metabolite acrolein antagonizes necroptosis and anti-cancer therapeutics

Dysregulated cell death leading to uncontrolled cell proliferation is a hallmark of cancer. Chemotherapy-induced cell death is critical for the success of cancer treatment but this process is impaired by metabolic byproducts. How these byproducts interfere with anti-cancer therapy is unclear. Here, we show that the metabolic byproduct acrolein derived from polyamines, tobacco smoke or fuel combustion, induces ferroptosis independently of ZBP1, while suppressing necroptosis in cancer cells by inhibiting the oligomerization of the necroptosis effector MLKL. Loss of the enzyme SAT1, which contributes to intracellular acrolein production, sensitizes cells to necroptosis. In mice, administration of an acrolein-trapping agent relieves necroptosis blockade and enhances the anti-tumor efficacy of the chemotherapeutic drug cyclophosphamide. Human patients with cancer coupled with a higher cell death activity but a lower expression of genes controlling polyamine metabolism exhibit improved survival. These findings highlight that the removal of metabolic byproducts improves the success of certain chemotherapies.

Arsenic exposure provoked prostatic PANoptosis by inducing mitochondrial dysfunction in mice and WPMY-1 cells

Inorganic arsenic, a widespread environmental toxicant, significantly contributes to prostate injury. However, the exact cellular mechanisms remain unclear. This study explored the involvement of pyroptosis, apoptosis, and necroptosis (PANoptosis), and their interconnections in arsenic-induced prostate injury. Herein, by employing in vitro (WPMY-1 cells exposed to arsenic for 48 h with or without reactive oxygen species (ROS) and mitochondrial ROS scavenger treatments) and in vivo (C57BL/6 mice were orally gavaged with arsenic and/or N-acetylcysteine for 90 consecutive days) models of arsenic-induced prostate injury and intervention, we demonstrated that sodium arsenite (NaAsO2) triggered mitochondrial damage-activated PANoptosis via the Bax/Bcl-xL/caspase-3/Gasdermin E (GSDME) pathway and the Z-DNA binding protein 1/receptor-interacting protein kinases 1 (RIPK1)/RIPK3/mixed lineage kinase domain-like protein (MLKL) signaling pathway. Notably, treatment with NaAsO2, GSDME, or MLKL knockdown in WPMY-1 cells increased the phenotype of PANoptosis. Mechanistically, the GSDME-N, GSDMD-N, p-MLKL, and cleaved caspase-3 protein levels were increased (1.4-, 2.67-, 3.51-, and 2.16-fold, respectively) in NaAsO2-treated GSDME knockdown WPMY-1 cells, whereas GSDME-N and cleaved caspase-3 protein levels were increased (1.30- and 1.21-fold, respectively) in NaAsO2-treated MLKL knockdown WPMY-1 cells. Our study highlights the crucial role of mitochondrial dysfunction in the initiation of PANoptosis during arsenic-induced prostate injury. Furthermore, we provide novel insights into the connections between apoptosis, pyroptosis, and necroptosis, indicating that GSDME and MLKL proteins may act as crucial regulators and potential therapeutic targets for arsenic-induced PANoptosis.

Z-Nucleic Acid Sensing and Activation of ZBP1 in Cellular Physiology and Disease Pathogenesis

Z-nucleic acid binding protein 1 (ZBP1) is an innate immune sensor recognizing nucleic acids in Z-conformation. Upon Z-nucleic acid sensing, ZBP1 triggers innate immune activation, inflammation, and programmed cell death during viral infections, mice development, and inflammation-associated diseases. The Zα domains of ZBP1 sense Z-nucleic acids and promote RIP-homotypic interaction motif (RHIM)-dependent signaling complex assembly to mount cell death and inflammation. The studies on ZBP1 spurred an understanding of the role of Z-form RNA and DNA in cellular and physiological functions. In particular, short viral genomic segments, endogenous retroviral elements, and 3'UTR regions are likely sources of Z-RNAs that orchestrate ZBP1 functions. Recent seminal studies identify an intriguing association of ZBP1 with adenosine deaminase acting on RNA-1 (ADAR1), and cyclic GMP-AMP synthase (cGAS) in regulating aberrant nucleic acid sensing, chronic inflammation, and cancer. Thus, ZBP1 is an attractive target to aid the development of specific therapeutic regimes for disease biology. Here, we discuss the role of ZBP1 in Z-RNA sensing, activation of programmed cell death, and inflammation. Also, we discuss how ZBP1 coordinates intracellular perturbations in homeostasis, and Z-nucleic acid formation to regulate chronic diseases and cancer.

African swine fever virus enhances viral replication by increasing intracellular reduced glutathione levels, which suppresses stress granule formation

African swine fever virus (ASFV) is a DNA virus that has significantly impacted the global swine industry. Currently, there are no effective therapies or vaccines against ASFV. Stress granules (SGs), known for their antiviral properties, are not induced during ASFV infection, even though reactive oxygen species (ROS) are generated. The mechanism by which ASFV regulates SGs formation remains unclear. This study demonstrates that ASFV antagonises SGs formation and increases intracellular levels of reduced glutathione (GSH) levels. The use of the GSH inhibitor BSO and the activator NAC confirmed that the ASFV-induced increase in GSH helps to suppress SGs formation and influences viral replication. Additionally, this study revealed that ASFV enhances GSH by upregulating the antioxidant transcription factor NRF2, as well as factors involved in GSH synthesis and regeneration, such as GCLC, and those related to the ferroptosis pathway, such as SLC7A11. Furthermore, the study uncovered that ASFV manipulates intracellular GSH levels by activating the mitochondrial protein AIFM1. This regulatory mechanism helps the virus inhibit the formation of intracellular SGs, thereby creating an optimal environment for viral replication. These findings provide new insights into the molecular strategies employed by ASFV.

Chronic Oxidative Stress and Stress Granule Formation in UBQLN2 ALS Neurons: Insights into Neuronal Degeneration and Potential Therapeutic Targets

The pathogenesis of neurodegenerative diseases results from the interplay between genetic and environmental factors. Aging and chronic oxidative stress are critical contributors to neurodegeneration. UBQLN2, a ubiquitin-related protein, aids in protein degradation and protects against oxidative stress. In ALS neurons harboring UBQLN2 mutations, oxidative stress accelerates pathological changes, yet the precise mechanisms remain unclear. Using induced motor neurons (iMNs) derived from UBQLN2 P497H iPSCs, we observed ALS-like phenotypes, including TDP-43 mislocalization, increased cell death, and reduced viability. Sodium arsenite (SA)-induced oxidative stress triggered stress granule formation, while autophagy dysfunction exacerbated neuronal degeneration. CHX and bosutinib treatments reduced ubiquitinated protein accumulation and alleviated degeneration, highlighting potential therapeutic pathways. These findings emphasize the role of chronic oxidative stress and stress granule formation in UBQLN2 ALS, offering insights into novel therapeutic targets.

Epithelial mitochondrial fission-mediated PANoptosis is crucial for ulcerative colitis and its inhibition by saquinavir through Drp1

Ulcerative colitis (UC) is characterized by increased cell death in intestinal epithelial cell (IEC), which compromises gut barrier function and activates inflammation. Aberrant mitochondrial dynamics have been implicated in various forms of cell death, but it is currently unclear if they play a role in IEC death and colitis pathogenesis. This study aims to investigate the contribution of aberrant mitochondrial dynamics to colitis progression using cellular models, animal models, and clinical samples. The results revealed that IEC in mice with Dextran sulfate sodium salt (DSS)-induced colitis exhibited dynamin-related protein 1 (Drp1)-mediated mitochondrial fission and Z-DNA binding protein 1 (ZBP1)-dependent PANoptosis, which is a combination of apoptosis, necroptosis, and pyroptosis. However, these processes and the pathogenesis of DSS-induced colitis were significantly attenuated in IEC-specific Drp1 heterozygous knockout mice. Importantly, ZBP1-PANoptosis and Drp1-mediated mitochondrial fission were observed in IEC of UC patients, exhibiting a positive correlation with disease severity. Mechanistically, hyperactivated mitochondrial fission induced mitochondrial reactive oxygen species production leading to PANoptosis through ZBP1 sulfenylation at Cys327 independently of its Zα domain. Saquinavir, an FDA-approved drug identified through in-silico screening alongside in vivo and in vitro experiments, inhibits mitochondrial fission thereby enhancing therapeutic efficacy in mice with colitis.

A histone deacetylase confers plant tolerance to heat stress by controlling protein lysine deacetylation and stress granule formation in rice

Understanding molecular mechanisms of plant cellular response to heat stress will help to improve crop tolerance and yield in the global warming era. Here, we show that deacetylation of non-histone proteins mediated by cytoplasmic histone deacetylase HDA714 is required for plant tolerance to heat stress in rice. Heat stress reduces overall protein lysine acetylation, which depends on HDA714. Being induced by heat stress, HDA714 loss of function reduces, but its overexpression enhances rice tolerance to heat stress. Under heat stress, HDA714-mediated deacetylation of metabolic enzymes stimulates glycolysis. In addition, HDA714 protein is found within heat-induced stress granules (SGs), and many SG proteins are acetylated under normal temperature. HDA714 interacts with and deacetylates several SG proteins. HDA714 loss of function increases SG protein acetylation levels and impairs SG formation. Collectively, these results indicate that HDA714 responds to heat stress to deacetylate cellular proteins, control metabolic activities, stimulate SG formation, and confer heat tolerance in rice.

Implications of inflammatory cell death-PANoptosis in health and disease

Regulated cell death (RCD) pathways, such as pyroptosis, apoptosis, and necroptosis, are essential for maintaining the body's balance, defending against pathogens, and eliminating abnormal cells that could lead to diseases like cancer. Although these pathways operate through distinct mechanisms, recent genetic and pharmacological studies have shown that they can interact and influence each other. The concept of "PANoptosis" has emerged, highlighting the interplay between pyroptosis, apoptosis, and necroptosis, especially during cellular responses to infections. This article provides a concise overview of PANoptosis and its molecular mechanisms, exploring its implications in various diseases. The review focuses on the extensive interactions among different RCD pathways, emphasizing the role of PANoptosis in infections, cytokine storms, inflammatory diseases, and cancer. Understanding PANoptosis is crucial for developing novel treatments for conditions involving infections, sterile inflammations, and cancer.

NBR1-mediated autophagic degradation of caspase 8 protects vascular endothelial cells against arsenite-induced apoptotic cell death

Vascular endothelial cells play a critical role in maintaining the health of blood vessels, but dysfunction can lead to cardiovascular diseases. The impact of arsenite exposure on cardiovascular health is a significant concern due to its potential adverse effects. This study aims to explore how NBR1-mediated autophagy in vascular endothelial cells can protect against oxidative stress and apoptosis induced by arsenite. Initially, our observations revealed that arsenite exposure increased oxidative stress and triggered apoptotic cell death in human umbilical vein endothelial cells (HUVECs). However, treatment with the apoptosis inhibitor Z-VAD-FMK notably reduced arsenite-induced apoptosis. Additionally, arsenite activated the autophagy pathway and enhanced autophagic flux in HUVECs. Interestingly, inhibition of autophagy exacerbated arsenite-induced apoptotic cell death. Our findings also demonstrated the importance of autophagy receptor NBR1 in arsenite-induced cytotoxicity, as it facilitated the recruitment of caspase 8 to autophagosomes for degradation. The protective effect of NBR1 against arsenite-induced apoptosis was compromised when autophagy was inhibited using pharmacological inhibitors or through genetic knockdown of essential autophagy genes. Conversely, overexpression of NBR1 facilitated caspase 8 degradation and reduced apoptotic cell death in arsenite-treated HUVECs. In conclusion, our study highlights the vital role of NBR1-mediated autophagic degradation of caspase 8 in safeguarding vascular endothelial cells from arsenite-induced oxidative stress and apoptotic cell death. Targeting this pathway could offer a promising therapeutic approach to mitigate cardiovascular diseases associated with arsenite exposure.

The ancient Z-DNA and Z-RNA specific Zα fold has evolved modern roles in immunity and transcription through the natural selection of flipons

The Zα fold specifically binds to both Z-DNA and Z-RNA, left-handed nucleic acid structures that form under physiological conditions and are encoded by flipons. I trace the Zα fold back to unicellular organisms representing all three domains of life and to the realm of giant nucleocytoplasmic DNA viruses (NCVs). The canonical Zα fold is present in the earliest known holozoan unicellular symbiont Capsaspora owczarzaki and persists in vertebrates and some invertebrates, but not in plants or fungi. In metazoans, starting with porifera, Zα is incorporated into the double-stranded RNA editing enzyme ADAR and reflects an early symbiont relationship with NCV. In vertebrates, Zα is also present in ZBP1 and PKZ proteins that recognize host-derived Z-RNAs to defend against modern-day viruses. A related Zα fold, also likely to bind Z-DNA, is present in proteins thought to modulate gene expression, including a subset of prokaryote arsR proteins and the p15 (PC4) family present in algae. Other Zα variants that probably play a more general role in the reinitiation of transcription include the archaeal and human transcription factor E and the human RNA polymerase 3 subunit C proteins. The roles in immunity and transcription underlie the natural selection of flipons.

Type I Interferon: Monkeypox/Mpox Viruses Achilles Heel?

Poxviruses are notorious for having acquired/evolved numerous genes to counteract host innate immunity. Chordopoxviruses have acquired/evolved at least three different inhibitors of host necroptotic death: E3, which blocks ZBP1-dependent necroptotic cell death, and vIRD and vMLKL that inhibit necroptosis downstream of initial cell death signaling. While this suggests the importance of the necroptotic cell death pathway in inhibiting chordopoxvirus replication, several chordopoxviruses have lost one or more of these inhibitory functions. Monkeypox/mpox virus (MPXV) has lost a portion of the N-terminus of its E3 homologue. The N-terminus of the vaccinia virus E3 homologue serves to inhibit activation of the interferon-inducible antiviral protein, ZBP1. This likely makes MPXV unique among the orthopoxviruses in being sensitive to interferon (IFN) treatment in many mammals, including humans, which encode a complete necroptotic cell death pathway. Thus, IFN sensitivity may be the Achille's Heel for viruses like MPXV that cannot fully inhibit IFN-inducible, ZBP1-dependent antiviral pathways.

Zbp1 gene: a modulator of multiple aging hallmarks as potential therapeutic target for age-related diseases

The Zbp1 gene has recently emerged as a potential therapeutic target for age-related diseases. Multiple studies have reported that Zbp1 plays a key role in regulating several aging hallmarks, including cellular senescence, chronic inflammation, DNA damage response, and mitochondrial dysfunction. Regarding cellular senescence, Zbp1 appears to regulate the onset and progression of senescence by controlling the expression of key markers such as p16INK4a and p21CIP1/WAF1. Similarly, evidence suggests that Zbp1 plays a role in regulating inflammation by promoting the production of pro-inflammatory cytokines, such as IL-6 and IL-1β, through activation of the NLRP3 inflammasome. Furthermore, Zbp1 seems to be involved in the DNA damage response, coordinating the cellular response to DNA damage by regulating the expression of genes such as p53 and ATM. Additionally, Zbp1 appears to regulate mitochondrial function, which is crucial for energy production and cellular homeostasis. Given the involvement of Zbp1 in multiple aging hallmarks, targeting this gene represents a potential strategy to prevent or treat age-related diseases. For example, inhibiting Zbp1 activity could be a promising approach to reduce cellular senescence and chronic inflammation, two critical hallmarks of aging associated with various age-related diseases. Similarly, modulating Zbp1 expression or activity could also improve DNA damage response and mitochondrial function, thus delaying or preventing the development of age-related diseases. Overall, the Zbp1 gene appears to be a promising therapeutic target for age-related diseases. In the current review, we have discussed the molecular mechanisms underlying the involvement of Zbp1 in aging hallmarks and proposed to develop effective strategies to target this gene for therapeutic purposes.

Flipons and small RNAs accentuate the asymmetries of pervasive transcription by the reset and sequence-specific microcoding of promoter conformation

The role of alternate DNA conformations such as Z-DNA in the regulation of transcription is currently underappreciated. These structures are encoded by sequences called flipons, many of which are enriched in promoter and enhancer regions. Through a change in their conformation, flipons provide a tunable mechanism to mechanically reset promoters for the next round of transcription. They act as actuators that capture and release energy to ensure that the turnover of the proteins at promoters is optimized to cell state. Likewise, the single-stranded DNA formed as flipons cycle facilitates the docking of RNAs that are able to microcode promoter conformations and canalize the pervasive transcription commonly observed in metazoan genomes. The strand-specific nature of the interaction between RNA and DNA likely accounts for the known asymmetry of epigenetic marks present on the histone tetramers that pair to form nucleosomes. The role of these supercoil-dependent processes in promoter choice and transcriptional interference is reviewed. The evolutionary implications are examined: the resilience and canalization of flipon-dependent gene regulation is contrasted with the rapid adaptation enabled by the spread of flipon repeats throughout the genome. Overall, the current findings underscore the important role of flipons in modulating the readout of genetic information and how little we know about their biology.

Cellular Stress: Modulator of Regulated Cell Death

Cellular stress response activates a complex program of an adaptive response called integrated stress response (ISR) that can allow a cell to survive in the presence of stressors. ISR reprograms gene expression to increase the transcription and translation of stress response genes while repressing the translation of most proteins to reduce the metabolic burden. In some cases, ISR activation can lead to the assembly of a cytoplasmic membraneless compartment called stress granules (SGs). ISR and SGs can inhibit apoptosis, pyroptosis, and necroptosis, suggesting that they guard against uncontrolled regulated cell death (RCD) to promote organismal homeostasis. However, ISR and SGs also allow cancer cells to survive in stressful environments, including hypoxia and during chemotherapy. Therefore, there is a great need to understand the molecular mechanism of the crosstalk between ISR and RCD. This is an active area of research and is expected to be relevant to a range of human diseases. In this review, we provided an overview of the interplay between different cellular stress responses and RCD pathways and their modulation in health and disease.

The Z-nucleic acid sensor ZBP1 in health and disease

Nucleic acid sensing is a central process in the immune system, with far-reaching roles in antiviral defense, autoinflammation, and cancer. Z-DNA binding protein 1 (ZBP1) is a sensor for double-stranded DNA and RNA helices in the unusual left-handed Z conformation termed Z-DNA and Z-RNA. Recent research established ZBP1 as a key upstream regulator of cell death and proinflammatory signaling. Recognition of Z-DNA/RNA by ZBP1 promotes host resistance to viral infection but can also drive detrimental autoinflammation. Additionally, ZBP1 has interesting roles in cancer and other disease settings and is emerging as an attractive target for therapy.