Science | Cuproptosis,copper-induced programmed cell death
Science?| Cuproptosis,copper-induced programmed cell death
Cell death is an important process in the body as it promotes the removal of unwanted cells. Several types of regulated programmed cell death include #apoptosis, #pyroptosis, #necroptosis, and #ferroptosis. Dixon et al. revealed that ferroptosis is a form of programmed cell death involving a series of morphological and biochemical features, including mitochondrial shrinkage and the accumulation of ROS. This article will cover a novel cell death form-#Cuproptosis.
Besides apoptosis, pyroptosis, necroptosis, and ferroptosis, a new form of programmed cell death was discovered and reported as cuproptosis, copper-induced cell death. As a cofactor for essential enzymes, copper is an indispensable trace metal to maintain protein functions. Intracellular copper concentration remains low under homeostatic control. Excess copper buildup and copper concentrations above the threshold maintained by homeostasis can be cytotoxic, but the mechanism of cell death triggered by copper remains elusive. A recent study “Copper induced cell death by targeting lipoylated TCA cycle protein” by Tsvetkov et al. published in?Science?proposed and demonstrated a copper-induced programmed cell death mechanism, in which copper-induced cell death through targeting lipoylated TCA cycle proteins[1].
Briefly, initiated by the excessive accumulation of copper through ionophores and transporters, copper directly binds to lipoylated DLAT in cells that are dependent on mitochondrial respiration, subsequently inducing aberrant oligomerization of DLAT and the formation of DLAT foci. The resulting increase of insoluble DLAT levels leads to proteotoxicity and cell death [Fig. 1].
Ferrodoxin-1 (FDX1), a substrate of elesclomol, is an upstream regulator of protein lipoylation and is required for DLAT lipoylation. Additionally, as a reductase, FDX1 is known to reduce Cu (II) ions to the more toxic Cu(I) ions, subsequently leading to the inhibition of Fe-S cluster synthesis and reduction of Fe-S cluster proteins.
Copper homeostasis is mainly regulated by copper importer SLC31A1 and the copper exporters ATP7A and ATP7B.
In the copper dysregulation syndromes #Menkedisease and #Wilsondisease, the genes encoding these transporters are mutated. In the steady state of copper, ATP7A and ATP7B play essential roles in copper homeostasis, including intracellular copper delivery for inclusion in metalloproteins, membrane trafficking, and export of excess copper from cells. Cell death caused by dysregulation of copper homeostasis is comparable to the cytotoxic effect caused by copper shuttling into the cell via copper ionophores (the copper-binding small molecules).
In this study, the cytotoxic effects of 1,448 copper ionophores with distinct structures were evaluated in 489 different cell lines [Fig. 2A]. As a highly lipophilic Cu (II) carrier, Elesclomol alone does not affect cell growth. But adding copper significantly increases sensitivity to Elesclomol, while supplementation with other metals, including iron, cobalt, zinc, and nickel, did not increase cell death [Fig 2B]. Notably, the addition of the copper chelator TTM abolished the cell growth inhibition activity by a combination of Elesclomol and copper [Fig. 2C],
confirming that copper ionophore-induced cell death is mainly dependent on the accumulation of intracellular copper. Treatment of cells with other copper ionophores such as NSC-319726 and Disulfiram showed the same results as elesclomol [Fig 3D-E].
No cleavage or activation of caspase 3 activity was observed in elesclomol induced-cell death. [Fig. 3D] When key effectors of apoptosis BAX and BAK1 were knocked out or when cells were co-treated with pan-caspase inhibitors (Z-VAD-FMK and Boc-D-FMK), the inhibition activity of elecsclomol remained intact, [Fig. 3E], suggesting that the copper-induced cell death is not through the apoptotic pathway. Moreover, pre-treatments with inhibitors of ferroptosis (Ferrostatin-1), Necroptosis (Necrostatin-1), and oxidative stress (N-acetyl cysteine) did not affect copper ionophore-induced cell death, [Fig 3C (Fig 1G from the original article)], indicating the existence of a distinct cell death pathway.
Cells that rely on mitochondrial respiration are more sensitive to copper ionophores than cells undergoing glycolysis [Fig. 4A]. In cell viability assays, cells pretreated with the ferroptosis inducer ML162 responded differently to various agents affecting mitochondrial functions compared to copper ionophores [Fig 4B].
Copper toxicity to the cells remained unchanged when cells were pretreated with the mitochondrial uncoupler FCCP, indicating that mitochondrial respiration is required for copper-induced cell death [Fig. 4C]. Although copper toxicity declined under hypoxic conditions, the addition of the HIF prolyl hydroxylase inhibitor FG-4592 showed no effect on copper ionophore induced-cell death under normoxic conditions [Fig 4D]. It was observed that copper ionophores significantly reduced the spare capacity of respiration [Fig 4E]. These results support that copper ionophore induced-cell death is regulated by mitochondrial respiration.
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Using a genome-wide #CRISPR-Cas9 positive selection screening, seven key genes were identified that play a role in copper-induced cell death, including FDX1 (encoding a direct target of elesclomol), and LIPT1, LIAS, DLD (three genes encoding lipoic acid pathway), or DLAT, PDHA1, and PDHB (encoding protein targets of lipoylation) [Fig 5A-C]. Individual gene knockout studies further confirmed that FDX1 and protein lipoylation are key regulators of copper ionophore-induced cell death [Fig.5D-E]. Therefore, Tsvetkov et al. thought that FDX1 was hypothesized to be an upstream regulator of protein thioctyl modification.
Correlation analysis of gene dependencies from the Cancer Dependency Map indicated that the FDX1 and components of the lipoic acid pathways were highly correlated across the panel of cell lines [Fig. 6A]. Immunohistochemistry staining results further confirmed this significant correlation [Fig. 6B-6C]. FDX1 knockout abolished protein lipoylation and resulted in a significant decrease in cellular respiration [Fig. 6D-E]. Furthermore, accumulation of pyruvate and α-ketoglutarate and depletion of succinate were observed followed deletion of FDX1 [Fig. 6F]. These results suggest that FDX1 is an upstream regulator of protein lipoylation.
Some studies have reported that the dissociation constants of copper ions and free fatty acids are 10-17, which indicates that copper ions may bind directly to thiocylated proteins. DLAT and DLST proteins purified from cell lysates bound to copper-charged resin but not to cobalt or nickel resins [Fig. 7A]. FDX1 knockout abolished protein lipoylation and the resulting naked DLAT and DLST no longer bound copper [Fig. 7B-C], lipoylation is thus a prerequisite for copper binding. Immunofluorescence imaging results support that copper binding leads to the toxic aggregation of lipoylated DLAT [Fig 7D]. These results also suggested that the toxicity of thioacylated proteins after copper ionophore treatment is mediated by their abnormal oligomerization.
Proteomic analysis of control and elesclomol treatment showed the downregulation of Fe-S cluster genes [Fig 7E] and loss of Fe-S cluster proteins by copper ionophore treatment (Data not shown). These findings indicate that copper can destabilize Fe-S-containing proteins.
The copper importer SLC31A1 (CTR1) and copper exporters ATP7A and ATP78 regulate homeostatic state of copper and normally keep intracellular copper concentration low. Overexpression of SLC1A1 in HEK293T and ABC1 cells was found to significantly increase sensitivity to physiological copper concentrations. [Fig 8B] Treatment of SLC31A1 overexpressed cells with copper resulted in the reduction of protein lipoylation and Fe-S cluster protein level, as well as increase of HSP70 [Fig. 8C].
The use of ferrodeath, necrotizing apoptosis, and inhibitors of apoptosis in cells overexpressing SLC31A1 did not affect copper-induced cell death, but copper chelators alleviated the cell-killing effect produced by copper ionophore. Whereas copper chelators, FDX1 KO and LIAS KO each partially rescued cells from copper-induced cell death [Fig 8D-E]. Tsvetkov et al. demonstrated this same mechanism of copper-induced cell death in vivo. In Menke’s disease-associated?Atpb7b?/??mice, it showed that the Fe-S cluster and lipoylated proteins were significantly reduced and Hsp70 protein was significantly increased compared with those in wild-type mice, further illustrating that excessive intracellular copper accumulation leads to cell death in vivo.These animal model results are in line with the copper ionophore-induced cellular effects.
Conclusion:
In this study, a novel type of programmed cell death, cuproptosis, was proposed and demonstrated. In this pathway, excess copper triggers abnormal aggregation of lipoylated proteins in TCA cycle and clearance of Fe-S cluster proteins, which is associated with upstream regulation by FDX1, ultimately leading to cell death.
References